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Graphene on Ultra-Fine 200 Mesh Copper TEM Grids

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Graphene coated TEM Grids

Product Name	Graphene On Ultra-Fine 200 Mesh Copper TEM Grids
Stock No.	NCZ-GSW-0014
Purity	> 99.9%
Graphene Film
FET Electron Mobility on Al₂O₃	2000 cm²/Vs
Hall Electron Mobility on SiO₂/Si	4000 cm²/Vs
Sheet Resistance	450±40 Ω/sq (1cm x1cm)

CAS No.: 7782-42-5 Characteristics

Four thicknesses of CVD graphene: Available in either 1, 2, 3-5 or 6-8 layers

TEM Substrate: Microporous Copper TEM Grids with Beryllium-Copper Support Aperture

Graphene coverage of the TEM grid is better than 75%

Appearance The graphene film appears as a near-transparent to light-grey film on the surface of the red-brown microporous copper TEM grid. For support, the TEM grid is attached using epoxy to a gold-colored beryllium-copper disk with a 2x1mm aperture.

Type	Thickness of the Graphene	Transparency	TEM Grid/AFM Substrate	Support Film
1 Layer	~0.35 nm	~96.4%	200 Mesh Copper Grid	N/A
2 Layers	~0.7 nm	~92.7%	200 Mesh Copper Grid	N/A
3-5 Layers	1.0-1.7 nm	~85.8-90.4%	200 Mesh Copper Grid	N/A
6-8 Layers	2.1-2.8 nm	~78.5-83.2%	200 Mesh Copper Grid	N/A

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Graphene Oxide Powder

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Graphene Oxide

Graphene Oxide Powder

MF	C
Chemical Name	Graphene Oxide, GO
Purity	≥ 99%
Diameter	0.5 – 3 μm
Thickness	0.3- 2 nm
Number of Layers	1-10 (Customization possible)
Color	Brown
Specific Area	500-700 m2/g
Form	Dried Powder
Product Number	NCZC200120
CAS Number	7782-42-5
Application	For Research Use Only

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What Is the Difference Between Graphene Oxide (GO) And Reduced Graphene Oxide (rGO)?

Whаt іѕ grарhеnе оxіdе?

Bесаuѕе grарhеnе іѕ expensive аnd relatively dіffісult tо рrоduсе, grеаt еffоrtѕ аrе bеіng mаdе tо fіnd еffесtіvе аnd inexpensive wауѕ tо produce аnd uѕе graphene dеrіvаtіvеѕ оr related mаtеrіаlѕ. Grарhеnе оxіdе (GO) іѕ оnе ѕuсh material – іt іѕ a ѕіnglе аtоmіс lауеr mаtеrіаl produced bу thе роwеrful аnd inexpensive аbundаnсе оf graphite oxidation. Grарhеnе оxіdе іѕ аn oxidized fоrm оf grарhеnе, bоund tо оxуgеn-соntаіnіng grоuрѕ. It іѕ соnѕіdеrеd еаѕу tо рrосеѕѕ аѕ іt іѕ dіѕреrѕіblе іn wаtеr (аnd оthеr solvents) аnd саn еvеn bе uѕеd tо mаkе graphene. The GO іѕ nоt a gооd соnduсtоr, but thеrе аrе рrосеѕѕеѕ tо increase іtѕ рrореrtіеѕ. It іѕ gеnеrаllу sold аѕ a роwdеr, dіѕреrѕеd оr аѕ a coating оn ѕubѕtrаtеѕ.

Graphene оxіdе іѕ ѕуnthеѕіzеd using fоur bаѕіс mеthоdѕ: Staudenmaier, Hоfmаnn, Brodie, аnd Hummеrѕ. Thеrе аrе mаnу variations оf thеѕе mеthоdѕ, wіth іmрrоvеmеntѕ continually bеіng explored fоr bеttеr rеѕultѕ аnd сhеареr processes. Thе еffесtіvеnеѕѕ оf аn оxіdаtіоn рrосеѕѕ іѕ оftеn assessed bу thе carbon/oxygen rаtіоѕ оf grарhеnе oxide.

Whаt іѕ rеduсеd graphene oxide?

Whеn рrоduсеd, grарhеnе оxіdе typically hаѕ a wide vаrіеtу оf dіffеrеnt funсtіоnаl оxуgеn grоuрѕ рrеѕеnt: 1,2-ероxіdе аnd аlсоhоl grоuрѕ іn thе bаѕаl planes аnd carboxyl аnd kеtоnе grоuрѕ аt thе еdgеѕ. Graphene оxіdе саn еаѕіlу bе dіѕреrѕеd іn a vаrіеtу оf hіgh соnсеntrаtіоn ѕоlvеntѕ, еіthеr fоr аddіtіvе рrосеѕѕіng wіth оthеr mаtеrіаlѕ оr fоr thісk lауеr рrосеѕѕіng. Hоwеvеr, grарhеnе оxіdе dоеѕ nоt hаvе thе ѕаmе exceptional рhуѕісаl аnd еlесtrоnіс properties thаt mаkе grарhеnе unique. Regardless, GO саn bе rеduсеd whоllу оr раrtіаllу tо рrоduсе a grарhеnе-lіkе structure bу rеmоvіng thе оxуgеn funсtіоnаl grоuрѕ рrеѕеnt.

Rеduсеd graphene оxіdе саn bе аdjuѕtеd bу vаrуіng thе degree оf rеduсtіоn uѕіng thеrmаl reduction оr vаrіоuѕ forms оf сhеmісаl rеduсtіоn. Thеrmаl reduction uѕuаllу рrоduсеѕ a grеаtеr dеgrее оf rеduсtіоn thаn сhеmісаl рrосеѕѕеѕ, providing grеаtеr electrical соnduсtіvіtу. Hоwеvеr, duе tо thе hіgh tеmреrаturеѕ іnvоlvеd, thіѕ саn саuѕе dаmаgе tо іndіvіduаl flаkеѕ – еіthеr bу breaking thе flаkеѕ оr іntrоduсіng dеfесtѕ іn thе structure. On thе оthеr hаnd, chemical rеduсtіоn аllоwѕ rеtеntіоn оf flake sizes оf thе GO uѕеd, аѕ wеll аѕ a lоwеr dеnѕіtу оf flаkе dеfесtѕ.

Whаt іѕ thе dіffеrеnсе bеtwееn grарhеnе оxіdе (Gо) аnd rеduсеd graphene оxіdе (rgо)?

Graphene оxіdе (GO) іѕ usually рrоduсеd frоm a graphite fееdѕtосk аnd results іn a lаrgе numbеr оf ѕіnglе-lауеr mаtеrіаl mаіnlу wіth a lаrgе numbеr оf “dеfесtѕ,” whісh ѕіmрlу mеаnѕ thаt іt іѕ wrіnklеd аnd nоt сruѕhеd — a flаt plan containing аррrоxіmаtеlу 30-35% оxуgеn bу wеіght.

Rеduсеd grарhеnе oxide (rGO) іѕ whаt уоu gеt bу removing a lаrgе percentage оf thе оxуgеn соntеnt from GO. It uѕuаllу rеѕultѕ іn a material thаt hаѕ approximately 5% оr lеѕѕ оxуgеn bу wеіght.

Thеѕе mаtеrіаlѕ compare dіffеrеntlу wіth grарhеnе nanoparticles (PNBѕ), аѕ PNBѕ саn hаvе multірlе саrbоn lауеrѕ оf uр tо 10 tо 20 оr mоrе, but wіth a vеrу low oxygen lеvеl. Thіѕ іѕ іmроrtаnt bесаuѕе thе inclusion оf оxуgеn rеduсеѕ оr еlіmіnаtеѕ thе electrical conductivity оf graphene, whісh іѕ оftеn оnе оf thе dеѕіrаblе properties.

Sіmрlу рut, wе саn еxрlаіn thе dіffеrеnсе bеtwееn GO аnd rGO. In GO thеrе іѕ mоrе oxygen-related funсtіоnаl grоuр (Ex -OH, COOH – еtс.) And wе knоw thаt mоrе oxide related thіngѕ аrе nоt gооd fоr mаnу applications, ѕо wе nееd tо rеmоvе thіѕ оxуgеn funсtіоnаl grоuр using ѕоmе рurіfісаtіоn tесhnіԛuеѕ. Nоw wе hаvе a lеѕѕ oxygen-related funсtіоnаl grоuр іn Gо, thеrеfоrе, іn rGO, wе hаvе lеѕѕ oxygen-related function grоuр аnd аrе gооd fоr mаnу аррlісаtіоnѕ.

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Graphene Oxides Solution

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Graphene Oxide

MF	C
Chemical Name	Graphene Oxide, GO
Purity	≥ 99.9%
Diameter	0.5 – 3 μm
Thickness	0.55- 2 nm
Number of Layers	1-10 (Customization possible)
Color	Brown
Specific Area	500-700 m2/g
Form	Dispersion/Solution
Product Number	NCZC2001
CAS Number	7782-42-5
Solvent	H2O (Ask for customization)

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Graphene Paste

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Graphene Paste and Dispersion

MF	C
Chemical Name	Graphene
Purity	≥ 99.9%
Diameter	4-6 μm
Thickness	0.55- 3.74 nm (Customization possible)
Number of Layers	1-10 (Customization possible)
Color	Black
Specific Area	500-700 m2/g
Form	Dispersion/Solution/Paste
Product Number	NCZC1005
CAS Number	7782-42-5
Content of Graphene in Water	1.0-1.5 wt%
Content of Dispersants in Water	0.2-0.75 wt%
Solvents	Water, NMP, DMF, Acetonitrile, DMSO, etc.

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Graphene Sheets Powder

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Pure Pristine Graphene Powder

MF	C
Chemical Name	Pure Pristine Graphene Powder
Purity	≥99.9%
Diameter	2-10 µm (Customization possible)
Thickness	0.55- 3.74 nm (Customization possible)
Number of Layers	1-10 (Customization possible)
Color	Black
Specific Area	>500 m2/g
Form	Nanopowder
Product Number	#NCZC1001
CAS Number	7782-42-5

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Graphene Solution

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Pristine Graphene Dispersion

MF	C
Chemical Name	Graphene Dispersion
Purity	≥99.9%
Diameter	0.5 – 3 μm
Thickness	0.55- 3.74 nm
Number of Layers	1-10 (Customization possible)
Color	Black
Specific Area	500-700 m2/g
Form	Dispersion/Solution
Product Number	NCZC1004
CAS Number	7782-42-5
Content of Graphene in Water	0.4-0.5 wt% (Customization possible)
Content of Dispersants in Water	0.5 wt%

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Graphite nanoparticles

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Graphite Nanoparticles

Graphite Nanopowder

Nano Graphite Powder

MF:	C
Chemical Name:	Graphite
Purity:	> 99.99%
APS:	APS 80 nm (Size Customization possible)
Form:	Nanopowder
Product Number:	#NCZ3101
CAS Number	7782-42-5

Note: We supply different products of microparticles and Nanoparticles powder in all size range according to client’s requirements.

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Graphite Powder

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Product Name: Graphite Powder

Product	Graphite Powder
CAS No.	7782-42-5
Appearance	Powder
Purity	99.9%
APS	1 – 5 microns (can be customized)
Ingredient	C
Product Code	NCZ-AE-191

RELATED INFORMATION Storage Conditions: Airtight sealed, avoid light, and keep dry at room temperature. Please email us for the customization. Email: contact@nanochemazone.com

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Graphite Powder

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Graphite Powder

Natural Graphite Powder

Graphite Powder micron particles

MF:	C
Chemical Name:	Graphite Powder
Purity:	> 99.99%
APS:	40-50 µm (Size Customization possible)
Form:	Micro powder
Product Number:	NCZM109
CAS Number	7782-42-5

Note: We can supply different size products of micro and Nano Size range powder according to client’s requirements.

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Graphitic Carbon Nitride (g-C3N4) Powder

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Graphitic Carbon Nitride

g-C3N4

Product Name	Graphitic Carbon Nitride
Formula	C3N4+xHy
Stock No.	NCZ-AM101-19
Appearance	Off-white to yellowish-brown powder
Molecular Weight	Varies with composition
Density	2.336 g/cm3
Average Particle Size	10-50 Micron (Customizable)
Specific Surface Area	>35 m2/g
Absorption	λmax 390 nm
Thermal Conductivity	1.25 W/m·K

Chemical Formula C3N4+xHy
Chemical purity ≥ 99.5 wt.%PEM fuel cell catalyst – better cost solutions
Color: off white yellow - brown
Density 2.336 g/cm3
Particle size, 1 to 50 microns
Specific surface area > 35 m2/gL
Thermal conductivity* 1.25 W/mK
Temperature stability: In inert atmosphere, 650°C

g-C3N4 RELATED INFORMATION

Storage Conditions: Airtight sealed, avoid light, and keep dry at room temperature. Please email us for the customization. Email: contact@nanochemazone.com

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Green Silicate Phosphor Powder

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Green Silicate Phosphor Powder

Product	Green Silicate Phosphor Powder
CAS No.	N/A
Appearance	Green Powder
Purity	≥99%, ≥99.9%, ≥95% (Other purities are also available)
APS	1-5 µM, 10-53 µM (Can be customized), Ask for other available size range.
Ingredient	P2SiO5
Density	5.1g/cm3
Molecular Weight	N/A
Product Codes	NCZ-MNO-184/25

Green Silicate Phosphor Description:

Green Silicate Phosphor Powder is one of the numerous advanced ceramic materials manufactured by Nanochemazone. Nanochemazone produces too many standard grades when applicable, including Mil Spec (military grade); ACS, Reagent and Technical Grade; Food, Agricultural and Pharmaceutical Grade; Optical Grade, USP and EP/BP (European Pharmacopoeia/British Pharmacopoeia) and follows applicable ASTM testing standards. Typical and custom packaging is available. Additional technical, research and safety (MSDS) information are available. Please request a quote above for more information on lead time and pricing.

Green Silicate Phosphor Powder Related Information:

Catalog No.	NCZ-MNO-184/25
Material	Silicate
Color	Green
Peak wavelength	540±2nm, 525±2nm
Excitation Range	275-460μm

Silicate Phosphors Description The green Silicate Phosphor is used for high-power positive white LED packaging, and has the characteristics of good thermal stability, long life, high brightness, uniform particle size, and high conversion efficiency. Moreover, it has a small attenuation for long-term use under high temperature and high humidity atmosphere and can be used for manufacturing an LED lighting device excellent in temperature and humidity resistance. Our LED phosphors can help LCD manufacturers produce displays with high color gamut, giving the screen unprecedented color realism and providing materials that match high-performance color filters. This series of Silicate Phosphors can be used in combination with other yellow or red phosphors to package warm white or special light LEDs. Silicate Phosphors Specifications

Item	GSP540	GSP525
Material	silicate	silicate
Density	5.1 g/cm3	5.1 g/cm3
Peak Wavelength	540±2 nm	525±2 nm
Domain Wavelength	557±1 nm	546±1 nm
CIE 1931	x=0.367±0.002	x=0.271±0.002
CIE 1931	y=0.592±0.002	y=0.626±0.002
Particle Size	D10=5±1 μm	D10=7±1 μm
	D50=15±1 μm	D50=18±1 μm
	D90=19±1 μm	D90=22±1 μm
FWHM	75±2 nm	66±2 nm
Excitation Range	275 μm-460 μm	275 μm-460 μm

Silicate Phosphors Applications - Human lighting - lighting that meets the needs of human natural clocks - General lighting - such as retail, residential, and professional lighting - Backlighting - for smartphones, monitors, televisions, etc. - Internal and external applications in the automotive industry Silicate Phosphors Packing 1 kg/ bottle, 10 kg/carton, 25 kg/drum, or as required. Our Silicate phosphor powder is tagged and labeled externally to ensure efficient identification and quality control. Great care is taken to avoid any damage which might be caused during storage or transportation.

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Green Silicon Carbide Powder

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Product Name: Green Silicon Carbide Powder

Product	Green Silicon Carbide Powder
CAS No.	409-21-2
Appearance	Green Powder
Purity	99.8%
APS	1 – 5 Microns (Can be customized)
Ingredient	SiC
Product Code	NCZ-AE-101

DESCRIPTION Green silicon carbide is made of petroleum coke and high-quality silica as main raw materials, adding salt as additive, and smelting at high temperature in resistance furnace. Green crystal, brittle and sharp, and has a certain thermal conductivity and electrical conductivity. Its crystallization has higher purity and hardness. Green silicon carbide is suitable for processing hard alloy, metallic and non-metallic material with hard and brittle feature such as copper, brass, aluminium, magnesslum, jewel, optical glass, ceramics, etc. Super Micropowder of it is also a kind of ceramics material. RELATED INFORMATION Storage Conditions: Airtight sealed, avoid light, and keep dry at room temperature. Please email us for the customization. Email: contact@nanochemazone.com

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H13 Alloy Steel Powder

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H13 Alloy Steel Powder

Product	H13 Alloy Steel Powder
CAS No.	N/A
Appearance	Gray to Dark Gray Powder
Purity	≥99%, ≥99.9%, ≥95%(Other purities are also available)
APS	1-5 µM, 10-53 µM (Can be customized), Ask for other available size range.
Ingredient	Fe-Cr-Mo-V-C
Density	7.80g/cm3
Molecular Weight	N/A
Product Codes	NCZ-DCY-351/25

H13 Alloy Steel Description:

H13 Alloy Steel Powder is one of the numerous advanced ceramic materials manufactured by Nanochemazone. Nanochemazone produces too many standard grades when applicable, including Mil Spec (military grade); ACS, Reagent and Technical Grade; Food, Agricultural and Pharmaceutical Grade; Optical Grade, USP and EP/BP (European Pharmacopoeia/British Pharmacopoeia) and follows applicable ASTM testing standards. Typical and custom packaging is available. Additional technical, research and safety (MSDS) information are available. Please request a quote above for more information on lead time and pricing.

H13 Alloy Steel Powder Related Information :

Composition	Content (%)
Carbon	0.32 – 0.45
Chromium	4.75 – 5.50
Molybdenum	1.10 – 1.75
Vanadium	0.80 – 1.20
Silicon	0.80 – 1.20
Manganese	0.20 – 0.50
Iron	Balance

Typical chemical composition of H13 alloy steel powder Properties and Characteristics

Property	Value
Density	7.8 g/cm³
Hardness (Annealed)	185 – 235 HB
Hardness (Heat Treated)	48 – 52 HRC
Tensile Strength (Heat Treated)	1800 – 2100 MPa
Yield Strength (Heat Treated)	1500 – 1800 MPa
Elongation (Heat Treated)	10 – 15%
Thermal Conductivity	28.6 W/m·K at 20°C
Melting Point	1427 – 1510°C

Typical properties of H13 alloy steel H13 alloy steel powder exhibits excellent dimensional stability, creep resistance, and thermal fatigue resistance, making it an ideal choice for various industrial applications. Its high hardness and wear resistance make it suitable for producing tools, dies, and components subjected to severe mechanical and thermal stresses. Applications

Application	Description
Extrusion Dies	Used for hot extrusion of metals, plastics, and other materials
Forging Dies	Utilized in hot forging processes for various metal components
Injection Molds	Employed in plastic injection molding for manufacturing plastic parts
Hot Shear Blades	Used in hot shearing operations for cutting metals at elevated temperatures
Casting Tooling	Utilized in the production of castings for various industries
Powder Metallurgy Tooling	Employed in the manufacturing of powder metallurgy components
Additive Manufacturing (AM) Components	Used for producing high-performance components via metal 3D printing techniques

Common applications of H13 alloy steel powder Specifications, Sizes, and Grades

Specification	Description
ASTM A681	Standard specification for tool steels alloy
DIN 1.2344	German standard for hot-work tool steel
JIS SKD61	Japanese Industrial Standard for hot-work die steel
BS BH13	British Standard for hot-working die steel
AISI H13	American Iron and Steel Institute specification for hot-work die steel

Common specifications and standards for H13 alloy steel H13 alloy steel powder is typically available in various particle size distributions, ranging from coarse to fine powders, to meet the requirements of different additive manufacturing processes, such as laser powder bed fusion (LPBF), electron beam powder bed fusion (EBPBF), and binder jetting. FAQs Q1: What makes H13 alloy steel powder suitable for additive manufacturing? A1: H13 alloy steel powder’s excellent mechanical properties, thermal resistance, and dimensional stability make it an ideal material for producing high-performance components via additive manufacturing processes like laser powder bed fusion and electron beam powder bed fusion. Q2: Can H13 alloy steel powder be used for other manufacturing processes besides additive manufacturing? A2: Yes, H13 alloy steel powder can also be used in conventional manufacturing processes like powder metallurgy, hot isostatic pressing (HIP), and metal injection molding (MIM). Q3: What are the typical post-processing steps for components made from H13 alloy steel powder? A3: Common post-processing steps for H13 alloy steel components include heat treatment, hot isostatic pressing (HIP), machining, and surface finishing operations like grinding, polishing, or coating. Q4: How does the particle size distribution of H13 alloy steel powder affect its performance in additive manufacturing? A4: The particle size distribution plays a crucial role in the flowability, packing density, and processability of the powder during additive manufacturing. Finer powders generally provide better resolution and surface finish, while coarser powders may exhibit better mechanical properties. Q5: Are there any specific safety precautions to consider when handling H13 alloy steel powder? A5: Yes, proper safety measures should be taken when handling H13 alloy steel powder, including the use of personal protective equipment (PPE), adequate ventilation, and proper disposal of waste materials. Additionally, precautions should be taken to prevent static discharge and dust explosions.

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H13 Powder

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H13 Powder

Product	H13 Powder
CAS No.	N/A
Appearance	Gray Powder
Purity	≥99%, ≥99.9%, ≥95%(Other purities are also available)
APS	1-5 µM, 10-53 µM (Can be customized), Ask for other available size range.
Ingredient	Fe-5Cr-1.3Mo-1V
Density	7.75g/cm3
Molecular Weight	N/A
Product Codes	NCZ-DCY-182/25

H13 Description:

H13 Powder is one of the numerous advanced ceramic materials manufactured by Nanochemazone. Nanochemazone produces too many standard grades when applicable, including Mil Spec (military grade); ACS, Reagent and Technical Grade; Food, Agricultural and Pharmaceutical Grade; Optical Grade, USP and EP/BP (European Pharmacopoeia/British Pharmacopoeia) and follows applicable ASTM testing standards. Typical and custom packaging is available. Additional technical, research and safety (MSDS) information are available. Please request a quote above for more information on lead time and pricing

H13 Powder Related Information :

Composition	Content (%)
Carbon	0.32 – 0.45
Chromium	4.75 – 5.50
Molybdenum	1.10 – 1.75
Vanadium	0.80 – 1.20
Silicon	0.80 – 1.20
Manganese	0.20 – 0.50
Iron	Balance

Typical chemical composition of H13 alloy steel powder Properties and Characteristics

Property	Value
Density	7.8 g/cm³
Hardness (Annealed)	185 – 235 HB
Hardness (Heat Treated)	48 – 52 HRC
Tensile Strength (Heat Treated)	1800 – 2100 MPa
Yield Strength (Heat Treated)	1500 – 1800 MPa
Elongation (Heat Treated)	10 – 15%
Thermal Conductivity	28.6 W/m·K at 20°C
Melting Point	1427 – 1510°C

Application	Description
Extrusion Dies	Used for hot extrusion of metals, plastics, and other materials
Forging Dies	Utilized in hot forging processes for various metal components
Injection Molds	Employed in plastic injection molding for manufacturing plastic parts
Hot Shear Blades	Used in hot shearing operations for cutting metals at elevated temperatures
Casting Tooling	Utilized in the production of castings for various industries
Powder Metallurgy Tooling	Employed in the manufacturing of powder metallurgy components
Additive Manufacturing (AM) Components	Used for producing high-performance components via metal 3D printing techniques

Common applications of H13 alloy steel powder Specifications, Sizes, and Grades

Specification	Description
ASTM A681	Standard specification for tool steels alloy
DIN 1.2344	German standard for hot-work tool steel
JIS SKD61	Japanese Industrial Standard for hot-work die steel
BS BH13	British Standard for hot-working die steel
AISI H13	American Iron and Steel Institute specification for hot-work die steel

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H13 Powder

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H13 Powder

Product	H13 Powder
CAS No.	N/A
Appearance	Gray Powder
Purity	≥99%, ≥99.9%, ≥95%(Other purities are also available)
APS	1-5 µM, 10-53 µM (Can be customized), Ask for other available size range.
Ingredient	Fe-5Cr-1.3Mo-1V
Density	7.80g/cm3
Molecular Weight	N/A
Product Codes	NCZ-DCY-183/25

H13 Description:

H13 Powder Related Information :

Storage Conditions: Airtight sealed, avoid light and keep dry at room temperature. Please contact us for customization and price inquiry Email: contact@nanochemazone.com Note: We supply different size ranges of Nano and micron as per the client’s requirements and also accept customization in various parameters. H13 tool steel powder H13 tool steel powder is an incredibly versatile and durable grade of tool steel powder commonly used to make tooling for hot work processes. This article provides a comprehensive overview of H13 powder metallurgy including composition, properties, processing, specifications, applications, advantages/disadvantages, and suppliers. H13 tool steel powder is an incredibly versatile and durable grade of tool steel powder commonly used to make tooling for hot work processes. This article provides a comprehensive overview of H13 powder metallurgy including composition, properties, processing, specifications, applications, advantages/disadvantages, and suppliers. Overview H13 tool steel powder is a versatile chromium-molybdenum-vanadium alloy steel that possesses excellent thermal shock and thermal fatigue resistance properties. It also demonstrates good ductility in hot working applications, high hardenability, and is exceptionally tough. H13 resists softening at temperatures up to 1000°F (540°C) making it an exceptional choice for manufacturing tooling that will withstand the rigors associated with aluminum die casting, forging dies, extrusion tooling, and more. When manufactured using powder metallurgy techniques, H13 powder delivers improved overall properties compared to conventionally produced H13 tool steel. Key advantages include: Fine, homogeneous microstructure Lack of segregation Superior mechanical properties Better dimensional control Higher hardness penetration Excellent polishability Composition Tool steel H13 is considered a chromium hot work tool steel. Here is a look at the chemical composition in weight percentage:

Element	Composition %
Carbon (C)	0.32-0.45
Chromium (Cr)	4.75-5.50
Molybdenum (Mo)	1.10-1.75
Vanadium (V)	0.80-1.20
Manganese (Mn)	0.20-0.50
Silicon (Si)	0.80-1.20
Iron (Fe)	Balance

The combination of chromium, molybdenum, and vanadium carbides in the microstructure give H13 excellent wear resistance at elevated temperatures up to 1000°F. Properties Here is an overview of the key physical and mechanical properties exhibited by H13 tool steel powder: Physical Properties Density: 7.3 g/cm3 Melting Point: 2785°F (1530°C) Mechanical Properties Tensile Strength: Annealed: 131,000 psi (900 MPa) Hardened & Tempered: 300,000 psi (2070 MPa) Yield Strength: Annealed: 76,000 psi (525 MPa) Hardened & Tempered: 262,000 psi (1800 MPa) Elongation: 8% Reduction of Area: 35% Hardness: Annealed: 217 HB Hardened & Tempered: 54 HRC The properties make H13 an exceptional choice for hot work dies and tooling. It maintains high strength and hardness at elevated temperatures. Processing H13 tool steel is available as conventional and powder metallurgy barstock as well as standard powders for additive manufacturing techniques. Here is an overview of how H13 powder is manufactured and processed to create dies, tooling, and components:

Atomization

Vacuum induction melting is used to create a liquid form of H13 that is then atomized into fine spherical powders. Common powder sizes range from 10 μm to 45 μm.

Compaction

The H13 powders are compacted into a die using presses delivering up to 100 tons of pressure. This forms a dense green compact ready for sintering.

Sintering

Green compacts are fired at temperatures between 2150-2300°F (1175-1260°C). This fuses the steel particles together creating >90% dense H13 tool steel parts.

Heat Treatment

Like wrought H13 tool steel, powder metallurgy H13 undergoes anneal, hardening, and tempering to achieve the desired mechanical properties.

Finishing

Sintered H13 products are machined, ground, and polished to final tolerances using conventional or EDM techniques. Proper heat treatment and finishing ensures parts have suitable compatibility with aluminum, zinc, lead, tin, copper, iron, nickel, and titanium alloys commonly used in hot work applications. Specifications H13 tool steel powder products are manufactured to meet various classifications: ASTM A681 ISO 4957 X40CrMoV5-1 DIN 1.2344 Typical size ranges include:

Form	Sizes
Powders	10-45 μm
Green compacts	Up to 40” x 20” x 6”
Sintered parts	Varied based on application

Applications Here are some of the common applications which leverage the unique properties of H13 tool steel powder: Hot Work Tooling Aluminum Die Casting Forging Dies Extrusion Tooling Plastic Mold Tooling Injection Molds Blow Molds Vacuum Forming High Temperature Processing Handling Molten Materials Holding Thermal Energy H13 powder tool steel proves highly effective for any tooling, dies, or components needing to withstand the extreme environment inside hot work machinery and equipment. H13 Powder vs Cast H13 Tool Steel There are a few key differences between H13 produced using conventional casting methods versus H13 fabricated with powder metallurgy techniques:

Parameter	H13 Cast	H13 Powder
Composition control	Less consistent composition	Very consistent composition
Segregation	High degree of segregation	No segregation
Uniformity	Not homogeneous	Very homogeneous
Density	90-92%	Up to 100% density
Typical hardness	50-51 HRC	Up to 56 HRC
Dimensional accuracy	+/- 0.5%	+/- 0.1% or better
Surface finish polishing	Moderate	Excellent

The molecular consistency and regularity of H13 steel powders enable superior overall mechanical properties. As a result, powder-based H13 tool steel provides better performance and longer life compared to cast tooling-grade products. FAQs Q: What’s the difference between H11, H12, H13, and H14 tool steel grades? A: The primary differences relate to chemical composition resulting in varied heat and wear resistance. H13 offers a good balance of toughness, hardness, and thermal properties for most hot work requirements. Q: Can you 3D print with H13 tool steel powder? A: Yes, H13 is readily weldable using laser powder bed fusion and binder jetting additive techniques to fabricate complex geometries impossible with conventional methods. Q: Is H13 tool steel powder corrosion resistant? A:H13 tool steel is known for its impressive strength and hardness, which is why it’s often used in high-stress applications like injection molding and die casting. However, when it comes to corrosion resistance, H13 isn’t particularly notable. It’s not as vulnerable as some other steels, but it’s not highly resistant either.

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H13 Powder

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H13 Powder

Product	H13 Powder
CAS No.	7439-89-6
Appearance	Gray Metallic Powder
Purity	≥99%, ≥99.9%, ≥95%(Other purities are also available)
APS	1-5 µM, 10-53 µM (Can be customized), Ask for other available size range.
Ingredient	Fe-Cr-Mo-V
Density	7.80g/cm3
Molecular Weight	N/A
Product Codes	NCZ-DCY-344/25

H13 Description:

H13 Powder Related Information :

Storage Conditions: Airtight sealed, avoid light and keep dry at room temperature. Please contact us for customization and price inquiry Email: contact@nanochemazone.com Note: We supply different size ranges of Nano and micron as per the client’s requirements and also accept customization in various parameters. A Comprehensive Guide to H13 Powder H13 powder is a high-performance tool steel powder that exhibits exceptional strength, toughness, and heat resistance. It belongs to the family of chromium hot-work tool steels, characterized by their ability to withstand high temperatures and mechanical stresses. The powder form of H13 allows for precise and efficient manufacturing processes, making it a popular choice in various industries. Overview of H13 Powder H13 is a versatile chromium-molybdenum-vanadium hot work tool steel exhibiting very good resistance to thermal fatigue cracking and wear resistance. It has high hardness retention at elevated temperatures making it suitable for tools and dies used for hot forming, forging and casting applications. Key characteristics of H13 powder include: Excellent hot hardness and thermal fatigue resistance Good wear resistance and toughness High hardenability for increasing hardness through heat treatment Excellent machinability in annealed state Can be polished to fine surface finish Available in various size ranges and morphologies H13 powder is used to produce hot work tooling needed across several industries including automotive, aerospace, mining, die-casting etc. This article provides a detailed overview of H13 powder. Chemical Composition of H13 Powder The typical chemical composition of H13 powder is:

Element	Weight %
Iron (Fe)	Balance
Chromium (Cr)	4.75-5.5%
Molybdenum (Mo)	1.1-1.75%
Vanadium (V)	0.8-1.2%
Manganese (Mn)	0.2-0.6%
Silicon (Si)	0.8-1.2%
Carbon (C)	0.32-0.45%

Properties of H13 Powder H13 powder possesses the following properties:

Property	Value
Density	7.3 g/cm3
Melting Point	1420-1460°C
Thermal Conductivity	24 W/mK
Electrical Resistivity	0.55 μΩ.cm
Young’s Modulus	200 GPa
Poisson’s Ratio	0.29-0.30
Tensile Strength	1900 MPa
Yield Strength	1650 MPa
Elongation	8-9%
Hardness	46-52 HRC

H13 maintains its hardness, strength and thermal fatigue resistance up to 600°C making it an ideal choice for hot work tool and die applications. Production Method for H13 Powder The common production methods for H13 powder include: Gas Atomization – High pressure inert gas used to atomize molten H13 alloy resulting in fine spherical powders with controlled size distribution. Water Atomization – High velocity water jet impacts and disintegrates molten metal stream into fine irregular powders. Lower cost but higher oxygen pickup. Mechanical Alloying – Ball milling of iron and alloying element powders followed by sintering and secondary atomization. Gas atomization provides the best control over particle characteristics like size, shape and microcleanliness. Applications of H13 Powder Typical applications of H13 powder include: Additive Manufacturing – Used in laser powder bed fusion and binder jetting to produce hot work tooling inserts, dies, blow molds etc. Thermal Spray Coatings – Applied using wire/powder arc spray methods to provide wear and heat resistant coatings. Metal Injection Molding – To manufacture small, complex hot work parts with tight tolerances like forging dies. Powder Metallurgy – Press and sinter process to produce hot forming tools and dies cost effectively. Welding Filler – Used as flux cored wire providing excellent resistance to heat and wear in the welded component. Specifications of H13 Powder H13 powder is available in various size ranges, shapes and grades including: Particle Size: From 10-45 microns for AM methods, up to 150 microns for thermal spray processes. Morphology: Spherical, irregular and blended particle shapes. Smooth spherical powder provides optimal flow. Grades: Conforming to AISI, DIN, ASTM, and other equivalent standards. Custom alloys also available. Purity: Oxygen content from 100-2000 ppm depending on production method. Lower oxygen levels offer better performance. Storage and Handling of H13 Powder H13 powder requires the following controlled storage and handling: Store in sealed containers under humidity control to prevent oxidation Avoid fine powder accumulation to minimize dust explosion hazards Use proper grounding and PPE when handling powder Prevent contact with sparks, flames or ignition sources Follow recommended safety practices from supplier SDS Inert gas glove box techniques are preferred for handling reactive alloy powders like H13. Inspection and Testing of H13 Powder Key quality control tests for H13 powder: Chemical analysis using OES or XRF to ensure correct composition Particle size distribution as per ASTM B822 standard Morphology analysis through SEM imaging Powder flow rate measured as per ASTM B213 standard Density determination by helium pycnometry Impurity testing by ICP-MS Microstructure characterization by X-ray diffraction Thorough testing ensures uniform chemistry, physical characteristics and microstructure suitable for application requirements. Comparison Between H13 and D2 Tool Steel Powders H13 and D2 are two tool steel powders compared:

Parameter	H13	D2
Type	Hot work steel	Cold work steel
Cr content	4.75-5.5%	11-13%
V content	0.8-1.2%	0.7-1.2%
Heat resistance	Excellent	Good
Wear resistance	Very good	Excellent
Toughness	Higher	Lower
Cost	Lower	Higher

H13 resists heat and thermal fatigue cracking whereas D2 offers very high wear resistance. H13 provides better toughness and lower cost. H13 Powder FAQs Q: How is H13 tool steel powder produced? A: H13 powder is commercially produced using gas atomization, water atomization and mechanical alloying followed by sintering. Gas atomization offers the best control of powder characteristics. Q: What are the main applications of H13 powder? A: The major applications of H13 powder include additive manufacturing, thermal spray coatings, metal injection molding, and powder metallurgy hot work tooling requiring excellent heat and wear resistance. Q: What is the recommended H13 powder size for binder jetting AM? A: For binder jetting process, the typical H13 powder size range is 20-45 microns with spherical morphology to enable good powder packing and binder infiltration. Q: Does H13 powder require any special handling precautions? A: Yes, it is recommended to handle H13 powder carefully under controlled humidity and inert atmosphere using proper grounding, ventilation and PPE. Q: Where can I purchase H13 powder suitable for hot forging dies? A: For hot work die applications, high purity H13 powder can be purchased from leading manufacturer.

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Hafnium Acetate Powder

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Hafnium Acetate Powder

Product	Hafnium Acetate Powder
CAS No.	15978-87-7
Appearance	White Powder
Purity	≥99%, ≥99.9%, ≥95%(Other purities are also available)
APS	1-5 µM, 10-53 µM (Can be customized), Ask for other available size range.
Ingredient	Hf(CH3COO)4
Density	N/A
Molecular Weight	414.67g/mol
Product Code	NCZ-CAS-172/25

Hafnium Acetate Description:

Hafnium Acetate Powder is one of the numerous advanced ceramic materials manufactured by Nanochemazone. Nanochemazone produces too many standard grades when applicable, including Mil Spec (military grade); ACS, Reagent and Technical Grade; Food, Agricultural and Pharmaceutical Grade; Optical Grade, USP and EP/BP (European Pharmacopoeia/British Pharmacopoeia) and follows applicable ASTM testing standards. Typical and custom packaging is available. Additional technical, research and safety (MSDS) information are available. Please request a quote above for more information on lead time and pricing.

Hafnium Acetate Powder Related Information:

Compound Formula	C8H12HfO8
Molecular Weight	414.67
Appearance	Solid
Melting Point	N/A
Boiling Point	N/A
Density	N/A
Solubility in H2O	N/A
Exact Mass	416.00 g/mol
Monoisotopic Mass	416.00 g/mol

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Hafnium Acetate Solution Powder

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Hafnium Acetate Solution Powder

Product	Hafnium Acetate Solution Powder
CAS No.	15978-87-7
Appearance	White Powder
Purity	≥99%, ≥99.9%, ≥95%(Other purities are also available)
APS	1-5 µM, 10-53 µM (Can be customized), Ask for other available size range.
Ingredient	Hf(CH3COO)4
Density	N/A
Molecular Weight	414.66g/mol
Product Code	NCZ-CAS-172/25

Hafnium Acetate Solution Description:

Hafnium Acetate Solution Powder is one of the numerous advanced ceramic materials manufactured by Nanochemazone. Nanochemazone produces too many standard grades when applicable, including Mil Spec (military grade); ACS, Reagent and Technical Grade; Food, Agricultural and Pharmaceutical Grade; Optical Grade, USP and EP/BP (European Pharmacopoeia/British Pharmacopoeia) and follows applicable ASTM testing standards. Typical and custom packaging is available. Additional technical, research and safety (MSDS) information are available. Please request a quote above for more information on lead time and pricing.

Hafnium Acetate Solution Powder Related Information:

Compound Formula	C8H12HfO8
Molecular Weight	414.66
Appearance	Liquid
Melting Point	N/A
Boiling Point	N/A
Density	N/A
Solubility in H2O	N/A
Exact Mass	416.00 g/mol
Monoisotopic Mass	416.00 g/mol

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Hafnium Boride Nanopowder

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Product Name: Hafnium Boride Nanopowder

Product	Hafnium Boride Nanopowder
CAS No.	12007-23-7
Form	Powder
Purity	≥ 99 %
APS	80 – 100 nm (can be customised)
Ingredient	HfB2
Product Code	NCZ-MS-120

RELATED INFORMATION Storage Conditions: Airtight sealed, avoid light, and keep dry at room temperature. Please email us for the customization. Email: contact@nanochemazone.com

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Hafnium Carbide Powder

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Product Name: Hafnium Carbide Powder

Product	Hafnium Carbide Powder
Colour	Gray Powder
Purity	≥ 99.9%
Particle size	1-10 µM (customizable)
Ingredient/MF	HfC
Product Code	NCZ-C-103/20
CAS Number	12069-85-1

Brief Description of Hafnium carbide powder HfC:

Hafnium carbide ( HfC) is a chemical compound of hafnium and carbon With a melting point of about 3900 °C it is one of the most refractory binary compounds known. However, it has low oxidation resistance, with the oxidation starting at temperatures as low as 430 °C Hafnium carbide is usually carbon deficient and therefore its composition is often expressed as HfCx (x = 0.5 to 1.0). It has a cubic (rock-salt) crystal structure at any value of x

Application of Hafnium carbide powder HfC:

Used for preparation of ultra-high temperature ceramics
The reactant in the synthesis of hafnium-containing organometallic polymers
Used as an additive in alloys
Used in coatings
Widely used in microelectronics, semiconductor, aerospace high-temperature resistant material, coating materials, ceramic materials, ceramic target material, etc.

Hafnium carbide Powder related Information

Please email us for the customization. Email: contact@nanochemazone.com Please contact us for customization and price inquiry Note: We supply different size ranges of Nano and micron as per the client’s requirements and also accept customization in various parameters.

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Hafnium Diboride Powder

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Product Name: Hafnium Diboride Powder

Product	Hafnium Diboride Powder
CAS No.	12007-23-7
Appearance	Powder
Purity	99.9%
APS	1 – 5 Microns (Can be customized)
Ingredient	HfB2
Product Code	NCZ-AE-168

RELATED INFORMATION Storage Conditions: Airtight sealed, avoid light, and keep dry at room temperature. Please email us for the customization. Email: contact@nanochemazone.com

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Hafnium Granules

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Product Name: Hafnium Granules

Product	Hafnium Granules
CAS No.	7440-58-6
Appearance	Granules
Purity	99.9%
APS	2 x 10 mm (can be customized)
Ingredient	Hf
Product Code	NCZ-AE-173

DESCRIPTION Hafnium Hf powder mainly used for :

Commonly used as X-ray cathode and tungsten wires manufacturing industry
Pure Hafnium with plasticity ,easy process , high temperature corrosion resistance is an important materials for the atomic energy industry
Hafnium thermal neutron capture cross section , is the idea neutron absorber , can be used as atomic reactor control rod and protection devices.

RELATED INFORMATION Storage Conditions: Airtight sealed, avoid light, and keep dry at room temperature. Please email us for the customization. Email: contact@nanochemazone.com

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Hafnium Hydride Powder

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Product Name: Hafnium Hydride Powder

MF:	HfH₂
Chemical Name	Hafnium Hydride
Color	Gray to black powder
Chemical family:	Metal Hydride
Purity:	99.9%
Molecular Weight:	180.51
Product Number:	NCZ-NSC-122/20
Cas Number:	12770-26-2

Hafnium Hydride Powder Related Information

Zirconium Hydride Powder, Titanium Hydride Powder, Vanadium Hydride Powder, Hafnium Hydride Powder, Zirconium Nitride Powder, Titanium Nitride Powder, Vanadium Nitride Powder, Nitrogen-Containing Chrome Powder, Nitrogen-Containing Manganese Powder. Metal hydrides are metals that have been bonded to hydrogen to form a new compound. Generally, the bond is covalent in nature, but some hydrides are formed from ionic bonds. Most hydrides behave as reducing agents in chemical reactions. Nickel metal hydride (NiMH) batteries rely on hydrides of rare-earth intermetallic compounds, such as lanthanum or neodymium.

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Hafnium Hydride Powder

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Hafnium Hydride Powder

Product Name: Hafnium Hydride Powder

Product	Hafnium Hydride Powder
Colour	Gray black
Purity	≥ 99.99%
Particle size	1-10 µM (customizable)
Ingredient/MF	HfH2
Product Code	NCZ-CE-157/20
CAS Number	3966-92-2

Application of Hafnium hydride powder:

Hafnium Hydride Powder is used in atomic energy industry and aerospace industry, the control rod material of nuclear energy reactor, can also be used as a small and powerful rocket propeller. Please email us for the customization. Email: contact@nanochemazone.com Please contact us for customization and price inquiry Note: We supply different size ranges of Nano and micron as per the client’s requirements and also accept customization in various parameters.

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Hafnium Metal Powder

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Product Name: Hafnium Metal Powder

Product	Hafnium Metal Powder
CAS No.	7440-58-6
Appearance	Powder
Purity	99.9%
APS	1 – 5 microns (can be customized)
Ingredient	Hf
Product Code	NCZ-AE-230

RELATED INFORMATION Storage Conditions: Airtight sealed, avoid light, and keep dry at room temperature. Please email us for the customization. Email: contact@nanochemazone.com

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Hafnium Nitride Powder

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Hafnium Nitride Powder

Product	Hafnium Nitride Powder
CAS No.	25817-87-2
Appearance	Gray to Black Powder
Purity	≥99%, ≥99.9%, ≥95%(Other purities are also available)
APS	1-5 µM, 10-53 µM (Can be customized), Ask for other available size range.
Ingredient	HfN
Density	13.31g/cm3
Molecular Weight	178.49g/mol
Product Codes	NCZ-DCY-148/25

Hafnium Nitride Description:

Hafnium Nitride Powder is one of the numerous advanced ceramic materials manufactured by Nanochemazone. Nanochemazone produces too many standard grades when applicable, including Mil Spec (military grade); ACS, Reagent and Technical Grade; Food, Agricultural and Pharmaceutical Grade; Optical Grade, USP and EP/BP (European Pharmacopoeia/British Pharmacopoeia) and follows applicable ASTM testing standards. Typical and custom packaging is available. Additional technical, research and safety (MSDS) information are available. Please request a quote above for more information on lead time and pricing

Hafnium Nitride Powder Related Information :

Molecular Weight	178.49
Appearance	Silver
Melting Point	2227 °C
Boiling Point	4602 °C
Density	13.31 g/cm3
Solubility in H2O	N/A
Electrical Resistivity	35.1 microhm-cm @ 25 °C
Electronegativity	1.3 Paulings
Heat of Fusion	6.0 Cal/gm mole
Heat of Vaporization	155 K-Cal/gm atom @ 4602 °C
Poisson's Ratio	0.37
Specific Heat	0.035 Cal/g/K @ 25 °C
Tensile Strength	N/A
Thermal Conductivity	0.230 W/cm/K @ 298.2 K
Thermal Expansion(25 °C)	5.9 µm·m-1·K-1
Vickers Hardness	1760 MPa

Young's Modulus 78 GPa Spherical Hafnium Powder can be used in the field of powder metallurgy to make alloys with high-temperature resistance, corrosion resistance, and other special properties. Nanochemazone supplies high-quality Spherical Hafnium Powder at a competitive price. Spherical Hafnium Powder Introduction High purity, high spherical degree, uniform particles, narrow distribution areas, larger specific surface area, high surface activity, spherical shape, good dispersion, high oxidation temperature, and luster. Corrosion resistance, soluble in hydrofluoric acid and royal water, at high temperature, easy to be soluble in hydrofluoric acid and form a fluoride complex. At high temperatures, hafnium can also combine directly with gases such as oxygen and nitrogen to form oxides and nitride ides. Spherical Hafnium Powder Applications Used as a cathode for X-ray tubes, alloys of hafnium and tungsten or molybdenum are used as electrodes for high-voltage discharge tubes. An ideal neutron absorber can serve as a control rod and protection device of the atomic reactor and can act as a rocket propellant. Alloys of Hafnium can serve as the front-edge protection layer of rocket nozzle and gliding reentry aircraft, and Hf-Ta alloy can make tool steel and resistive materials Hafnium powder is used as an added element in heat-resistant alloys, such as tungsten, molybdenum, and hafnium tantalum. Used as an additive of hydraulic oil, to prevent the volatilization of hydraulic oil during high-risk operations, and has a strong anti-volatile nature, with this characteristic, so it is generally used in industrial hydraulic oil. Medical hydraulic oil.

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Hafnium Oxide Nanoparticles

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Hafnium Oxide Nanoparticles

Hafnium Oxide Nanopowder

Nano Hafnium Oxide

MF	HfO2
Chemical Name	Hafnium Oxide
Purity	≥ 99.99%
APS	50-100 nm (Size Customization possible)
Form	Nanopowder
Product Number	NCZ3201
CAS Number	12055-23-1

Note: We supply different products of microparticles and Nanoparticles powder in all size range according to the client’s requirements.

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Hafnium Silicide Powder

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Hafnium Silicide Powder

Product Name: Hafnium Silicide Powder

Product	Hafnium Silicide Powder
CAS No.	12401-56-8
Appearance	Powder
Purity	99.9%
APS	1 – 5 Microns (Can be customized)
Ingredient	HfSi2
Product Code	NCZ-AE-137

RELATED INFORMATION

Storage Conditions: Airtight sealed, avoid light, and keep dry at room temperature. Please email us for the customization. Email: contact@nanochemazone.com

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Hafnium Silicide Powder

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Hafnium Silicide Nanoparticles

MF	HfSiO2
Chemical Name	Hafnium Silicide
Purity	≥ 99%
APS	50-100 nm, 1 to 5 um, 10 um, 325 Mesh (Size Customization possible)
Form	Gray Powder
Product Number	NCZ3244-20
CAS Number	12401-56-8

Note: We supply different products of microparticles and Nanoparticles powder in all sizes range according to the client’s requirements.

Characteristics: Hafnium silicide power has a high melting point, high corrosion resistance, high oxidation resistance, good electrical conductivity, high-temperature ductility, a binary alloy system the intermediate phase, dual characteristics of metals and ceramics.

Technical Parameter:

Product Name	MF	Purity	Particle Size	Melting Point	Density	Color
hafnium silicide	HfSi2	99%	1-5um	1680℃	8.02 g/cm3	gray

Chemical Composition:

HfSi2	Hf	Si	Zr	P	Fe	S	Ni
＞99%	＞75.2%	balance	1.76%	0.02%	0.15%	0.01%	0.05%

Application: Used in cermets, high-temperature oxidation-resistant coatings, high-temperature structural materials, and aviation, aerospace, and other fields.

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Hastelloy X Powder

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Hastelloy X Powder

Product	Hastelloy X Powder
CAS No.	26708-20-9
Appearance	Silvery-Gray Powder
Purity	≥99%, ≥99.9%, ≥95%(Other purities are also available)
APS	1-5 µM, 10-53 µM (Can be customized), Ask for other available size range.
Ingredient	NiCrMoFe
Density	8.89g/cm3
Molecular Weight	100g/mol
Product Codes	NCZ-DCY-201/25

Hastelloy X Description:

Hastelloy X Powder is one of the numerous advanced ceramic materials manufactured by Nanochemazone. Nanochemazone produces too many standard grades when applicable, including Mil Spec (military grade); ACS, Reagent and Technical Grade; Food, Agricultural and Pharmaceutical Grade; Optical Grade, USP and EP/BP (European Pharmacopoeia/British Pharmacopoeia) and follows applicable ASTM testing standards. Typical and custom packaging is available. Additional technical, research and safety (MSDS) information are available. Please request a quote above for more information on lead time and pricing

Hastelloy X Powder Related Information :

Metal Powder	Size	Quantity	Price/kg
Hastelloy X	15-45um	1KG	107
		10KG	79
		100KG	70

Hastelloy X Powder Overview Hastelloy X powder is a nickel-based superalloy powder with exceptional high temperature strength and outstanding oxidation and corrosion resistance properties. It retains mechanical properties up to 1150°C making it suitable for critical components in aerospace engines, industrial gas turbines, chemical processing, and molten metal handling. Hastelloy X powder can be used to fabricate parts from this high performance alloy via powder bed fusion additive manufacturing processes like laser powder bed fusion (LPBF) and electron beam powder bed fusion (EBM). This enables complex geometries to be printed directly from CAD data without the constraints of traditional casting and machining. Compared to conventional nickel superalloys, Hastelloy X has superior creep rupture strength thanks to strategic additions of other elements like cobalt and molybdenum. It resists oxidizing, reducing and neutral atmospheres up to extreme temperatures prolonging component service life. With additive manufacturing, designers can construct lighter Hastelloy X parts with conformal cooling channels and integrated assemblies not feasible previously. This guide covers Hastelloy X powder compositions, properties data, applications, printer parameters, and suppliers to leverage benefits of this alloy. Composition of Hastelloy X Powder Hastelloy X is a Ni-Cr-Fe-Co-Mo alloy with trace additions of other elements to enhance specific properties. The nominal composition by weight percent is:

Element	Ni	Cr	Fe	Co	Mo	W	Mn	Si
Weight %	bal.	21.5	18.5	12.5	9.0	0.6	0.5	0.5

Nickel is the main base element providing a FCC crystal matrix. It lowers coefficient of thermal expansion. Chromium helps with oxidation and corrosion resistance through a protective chromium oxide layer forming on the surface. Iron, cobalt and molybdenum strengthen the material with solid solution mechanisms. Cobalt also maintains ductility. Tungsten further improves high temperature strength via carbide formation. Trace elements like manganese and silicon enhance castability and hot workability. Modifications beyond this standard composition aim to tailor the alloy for specific requirements like higher strength or fabricability or to minimize certain elements. Properties of Hastelloy X Powder Hastelloy X possesses an excellent combination of high temperature strength, corrosion resistance, fabricability and weldability. Key attributes are:

Property	Value
Density	8.22 g/cm3
Melting Point	1350°C
Tensile Strength	760 MPa (at 20°C)<br>140 MPa (at 1090°C)
Elongation %	50% (at 20°C)
Thermal Conductivity	11.3 W/m-K
Coefficient of Thermal Expansion	13.0 μm/m-°C
Modulus of Elasticity	196-214 GPa
Poisson’s Ratio	0.29-0.32

Retains 55% of room temperature strength up to 900°C. Creep rupture strength exceeds 100 MPa for over 1000 hours at 980°C. Resists hot corrosion and oxidation in high velocity gases up to extreme temperatures. Protective Cr2O3 oxide layer forms. Fabricability is good owing to 45-55% cold workability and high temperature hot workability. Machinability is rated 35% of 303 stainless steel. Exhibits excellent weldability. Low carbon content minimizes carbide precipitation during welding. Printed Hastelloy X Properties Mechanical properties of AM Hastelloy X parts depend on build orientation, processing parameters and heat treatments. Isotropic properties are attainable in the annealed state. Example data:

Property	As-printed EBMF	As-printed LPBF
Tensile Strength	330 – 470 MPa	500 – 660 MPa
Yield Strength (0.2%)	230 MPa	320 MPa
Elongation at Break	37%	35%

Applications of Hastelloy X Hastelloy X sees heavy usage in: Aerospace: Combustion chambers, spray bars, tubes, cases, fasteners, and housings in aircraft engines and land-based power generation turbines given its extreme temperature and environmental resistance. Chemical Processing: Reformer tubes, cracking coils, heat exchangers, valve parts exposed to hydrocarbon processing and mixed industrial atmospheres at elevated temperatures seeking corrosion resistance. Molten Metal Processing: Crucibles, thermocouple sheaths, fasteners, and pump/valve components contacting molten glass, aluminum, zinc, lead, copper, steel and superalloys during casting, coating and smelting operations. Pollution Control: Ducting, stacks, scrubbers, fans, dampers handling hot acidic exhaust gases in waste incineration plants and coal-fired power stations which induce oxidation and corrosion. Metalworking: Hot forming dies, extrusion containers and tooling holding superalloys, titanium and refractory metals at high temperatures during thermo-mechanical processing where heat and wear resistance is vital. Hastelloy X Parts Made with Additive Manufacturing Benefits of additively manufacturing components in Hastelloy X include: Fabricating intricate cooling channels and bionic geometries improving functionality Consolidating assemblies to reduce part count Customizing alloys to further enhance properties Accelerated design iteration and parts on demand Reduced lead times and inventories Construction of complex sandwich structures with lattices Light weighting components through topology optimization Process Parameters for Printing Hastelloy X Powder LPBF and EBM involve spreading thin layers of metal powder ~20-100 microns thick and selectively melting areas based on 3D CAD data using a laser beam or electron beam respectively. Key parameters for Hastelloy X include: LPBF Settings

Parameter	Range
Laser power (W)	195 – 380 W
Scan speed (mm/s)	600-1550 mm/s
Beam size (μm)	50-200 μm
Layer thickness (μm)	20-50 μm
Hatch spacing (μm)	80-140 μm
Shielding gas	Argon

EBM Settings

Parameter	Range
Beam power (W)	2.0-3.5 kW
Beam speed (m/s)	1000-3000 m/s
Beam size (μm)	200
Layer thickness (μm)	50-200 μm
Line offset (μm)	100
Preheat temp (°C)	1000°C

Part density above 99% is achieved in both processes after stress relieving and hot isostatic pressing. Minimum feature sizes of ~100-200 microns are possible. Mechanical Testing Standards Key test methods used to evaluate the tensile, fatigue, fracture toughness and creep rupture properties of Hastelloy X material and powders include:

Standard	Title	Organization
ASTM E8	Tension Testing of Metallic Materials	ASTM
ASTM E23	Notched Bar Impact Testing	ASTM
ISO 6892	Metallic Materials Tensile Testing	ISO
AMS 2633A	Heat Treatment of Hastelloy X Parts	SAE

Post Processing of Additively Manufactured Hastelloy X Parts After printing, Hastelloy X parts must undergo the following post processing steps before putting into service: Support Removal Sacrificial supports are detached using wire EDM cutting or chemical dissolution where accessible. Stress Relieving To eliminate residual stresses from the layerwise buildup, heat gently under vacuum or inert gas to 760-980°C for 1-2 hours. Hot Isostatic Pressing HIP the entire print at 1120°C temperature and 100-200 MPa pressure for 3-6 hours to close internal voids and microporosity. Heat Treatment Solution annealing between 1150-1210°C ensures equilibrium microstructure and desired hardness. Surface Processing Additional surface treatments involve grinding, milling, polishing and shot peening to attain required surface roughness and finish. Quality Testing Test parts meet specifications for dimensions, material integrity, microstructure and mechanical properties per applicable standards. Conduct layerwise scanning. Buyer’s Guide – Hastelloy X Powder Bed 3D Printers Critical printer considerations for working with reactive alloys like Hastelloy X powder include: Precision – tight process controls for dimensional accuracy and repeatability over builds Inert Atmosphere – very high purity shielding gas to prevent material contamination Automation – powder handling systems to minimize oxygen exposure Quality Assurance – inline monitoring, closed loop feedback of melt pools and microstructure Smart Software – special scanning strategies adapting to thermal history and geometry Productivity – faster build rates through higher laser power and large build volumes Leading models include: 3D Systems DMP Factory 500 GE Additive Concept Laser Xline 2000R EOS M 400-4 4-laser system SLM Solutions Next Generation series Renishaw RenAM 500 Quad laser machine Future Outlook for Hastelloy X and Metal AM The applications for Hastelloy X components will expand within existing sectors as additive techniques enable newer possibilities combined with increasing economic viability: More common use directly 3D printing rocket combustion chambers, commercial jet engine parts, industrial gas turbine hot sections and power generation hardware given enhanced geometric, cooling and weight benefits. Additional chemical equipment like heat exchanger internals and process tanks with conformal channels printed as one body rather than welded sheet metal assemblies. Consolidating module assemblies and traditionally brazed joints for aerospace and semiconductor production equipment susceptible to vacuum and high purity corrosive atmospheres. Customized, unitized fuel injector assemblies and effusion cooling plates tailored to specific thermal environments in liquid propulsion systems and turbines. Increased adoption of patient matched implants like dental bridges and crowns taking advantage of biocompatibility. The future of metal AM itself is very positive due to greater affordability along with faster build rates and turnaround times. Manufacturing applications of the technology keep expanding. FAQs Q: What is Hastelloy X most known for regarding its alloy properties? A: Hastelloy X is most renowned for retaining high strength at extreme temperatures up to 1150°C along with superb corrosion resistance allowing it to endure hot oxidizing and reducing atmospheres in demanding environments. Q: What industries use Hastelloy X and its related superalloys the most? A: Aerospace is the leading consumer of Hastelloy X exploiting its heat resistance – over 50% usage. Next is chemical processing relying on corrosion resistance, followed by metal processing and pollution control applications. Q: What makes Hastelloy X better than other Ni-based superalloys for extreme environments? A: Strategic additions of iron, cobalt and molybdenum give Hastelloy X the highest strength among nickel alloys up to 1150°C. Other Ni superalloys either fall short of this max temperature or eventually get outperformed in rupture strength duration. Q: What is the typical cost per kg of Hastelloy X powder suitable for AM powder bed processes? A: Because Hastelloy X is a specialty powder tailored to demanding applications, its pricing ranges from $500 to $1000 per kg normally. This is 5-10X stainless steel costs for example. There is further markup for lower quantity orders. Q: Which 3D printing process works better for Hastelloy X – DMLS or EBM? A: Both LPBF and EBM can print fully dense Hastelloy X components. Laser based processes may offer better surface finish and dimensional precision down to ~50 microns detail. But EBM’s faster build rate makes it preferred for higher volume production applications. Q: What heat treatment is used for Hastelloy X parts after metal AM construction? A: The typical heat treatment cycle involves 1-2 hours of soaking between 1150°C to 1210°C after a 1080°C stress relief first. This homogenizes elements in the matrix providing desired phase balance and properties. Q: Is Hastelloy X harder or easier to machine than standard 304 or 316 stainless steel grades? A: Hastelloy X has nearly 50% lower machinability rating relative to common 300 series stainless steels because of its higher strength and work hardening characteristics. More rigid setups and appropriate tooling required. Q: Can you weld Hastelloy X superalloy using conventional fusion welding methods? A: Yes, Hastelloy X shows excellent weldability via gas tungsten arc welding (GTAW), plasma or laser beam techniques owing to low carbon and absence of strengthening precipitates along grain boundaries that can form brittle intermetallic phases. Use matching filler alloy. Q: What industries will drive future adoption of metal AM using alloys like Hastelloy X? A: Aerospace, medical, automotive and energy industries have some of the highest value applications for printed metal parts made from alloys which balance properties like temperature resistance, corrosion resistance and high strength where lightweight constructions confer significant benefits.

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Hastelloy X Powder

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Hastelloy X Powder

Product	Hastelloy X Powder
CAS No.	N/A
Appearance	Silvery-Gray Powder
Purity	≥99%, ≥99.9%, ≥95%(Other purities are also available)
APS	1-5 µM, 10-53 µM (Can be customized), Ask for other available size range.
Ingredient	NiCrMoFe
Density	8.22g/cm3
Molecular Weight	N/A
Product Codes	NCZ-DCY-276/25

Hastelloy X Description:

Hastelloy X Powder Related Information :

Storage Conditions: Airtight sealed, avoid light and keep dry at room temperature. Please contact us for customization and price inquiry Email: contact@nanochemazone.com Note: We supply different size ranges of Nano and micron as per the client’s requirements and also accept customization in various parameters. Best Hastelloy X Powder丨High temperature alloy Powder for 3D Printing Hastelloy X Powder holds a special place. It’s a nickel-based superalloy that has an extraordinary blend of properties, thanks to its composition which includes chromium, iron, and molybdenum. The high nickel content offers exceptional resistance to oxidation and corrosion. Overview of Hastelloy X Powder Hastelloy X is a nickel-based superalloy powder known for its excellent high temperature strength, oxidation resistance, and fabricability. It has applications in the aerospace, industrial, and energy industries where parts are exposed to extreme environments. This article provides a comprehensive guide to Hastelloy X powder. It covers the composition, properties, applications, specifications, suppliers, handling, inspection, comparisons, pros and cons, and frequently asked questions about this versatile alloy powder. Quantitative data is presented in easy-to-read tables for quick reference. Composition of Hastelloy X Powder Hastelloy X has a complex composition optimized for high temperature performance. The main alloying elements are nickel, chromium, iron, and molybdenum.

Element	Weight %	Role
Nickel	Balance	Matrix element, provides corrosion resistance
Chromium	21.5 – 23.5	Oxidation resistance, formation of protective Cr2O3
Iron	17 – 20	Solid solution strengthening
Molybdenum	8 – 10	Solid solution strengthening, creep resistance
Cobalt	1 max	Enhances hot workability
Manganese	1 max	Deoxidizer
Silicon	0.5 max	Deoxidizer
Carbon	0.15 max	Carbide former

Trace additions of boron, zirconium, and carbon are also made to optimize properties like creep resistance. The balance nickel content provides corrosion resistance. Properties of Hastelloy X Powder Hastelloy X exhibits an excellent combination of properties for high temperature applications:

Property	Description
High temperature strength	Excellent creep rupture strength up to 1150°C
Oxidation resistance	Resists oxidation in air up to 1200°C
Thermal fatigue resistance	Resists cracking during thermal cycling
Fabricability	Easy to form and weld compared to other superalloys
Corrosion resistance	Resists many oxidizing and reducing environments

Grain size control and thermomechanical processing modifies properties like tensile strength and ductility. Applications of Hastelloy X Powder The unique properties of Hastelloy X enable critical applications including:

Industry	Applications
Aerospace	Jet engine combustion liners, afterburners, exhaust parts
Industrial	Reformer tubes, heat treatment equipment
Energy	Nuclear & fossil fuel power generation, chemical processing
Automotive	Exhaust system components, turbocharger parts

The oxidation resistance allows thin section capabilities needed for jet engine combustion liners. It also suits the extremes of chemical processing vessels and tubing. Specifications of Hastelloy X Powder Hastelloy X powder is commercially available with specifications per alloy grade:

Parameter	Specification
Alloy grades	Hastelloy X, B3, BC3, BN
Particle size	15-45 microns, 45-105 microns
Particle shape	Spherical, irregular morphology
Apparent density	2.5-4.5 g/cc
Tap density	4-6 g/cc
Purity	>99.9%
Oxygen content	<1000 ppm
Moisture content	<0.2%

Other custom size distributions, purity levels, particle shapes and alloy modifications are possible for special applications. Handling and Storage of Hastelloy X Powder As a reactive metal powder, Hastelloy X requires controlled handling and storage: Store in sealed containers in a cool, dry environment Avoid contact with moisture, acids, halogen compounds Ground containers and transfer equipment to prevent static buildup Use spark-proof tools and minimize dust generation Prevent accumulation of dusts to reduce explosion risk Wear appropriate PPE and avoid inhalation of powders Proper precautions during handling, storage and processing are critical for safety and quality. Inspection and Testing of Hastelloy X Powder Hastelloy X powder batches are tested to ensure they meet specifications:

Test Method	Parameters Checked
Sieve analysis	Particle size distribution
Apparent density	Powder flowability
Tap density	Packed density
Scanning electron microscopy	Particle morphology
Energy dispersive X-ray	Chemistry, alloy composition
X-ray diffraction	Phases present
Inductively coupled plasma	Trace element analysis

Sampling and testing as per ASTM standards ensures batch-to-batch consistency and quality. Comparing Hastelloy X to Alternatives Hastelloy X has advantages and limitations compared to other superalloys:

Alloy	Oxidation Resistance	Fabricability	Cost
Hastelloy X	Excellent	Good	High
Inconel 625	Good	Excellent	Medium
Haynes 230	Excellent	Poor	Very High
Inconel 718	Medium	Fair	Medium

Hastelloy X provides the best combination of oxidation resistance, fabricability, and cost for many high temperature applications. Pros and Cons of Hastelloy X Powder

Pros	Cons
Excellent high temperature strength	Expensive compared to stainless steels
Outstanding oxidation resistance	Lower fabricability than Inconel 625
Thermal fatigue resistance	Susceptible to embrittlement at lower temperatures
Ease of welding and machining	Requires controlled handling and processing
Resists many corrosive environments	Limited data available compared to popular alloys

Hastelloy X enables exceptional performance but requires care in processing and has high material cost. Frequently Asked Questions about Hastelloy X Powder Here are answers to some common questions about Hastelloy X powder: Q: What is Hastelloy X used for? A: Hastelloy X is used in aircraft engines, industrial furnaces, chemical processing, and power generation applications where strength and oxidation resistance at extreme temperatures are required. Q: What is the difference between Hastelloy X and Hastelloy C? A: Hastelloy X has addition of iron and higher molybdenum content. This gives better fabricability and high temperature strength compared to Hastelloy C which relies only on chromium for oxidation resistance. Q: Is Hastelloy X weldable? A: Yes, Hastelloy X has good weldability compared to other nickel superalloys, making it suitable for fabrication of complex components. Proper welding process and parameters must be used to avoid cracking. Q: What is the temperature range of Hastelloy X? A: It maintains good strength and oxidation resistance up to 1100°C for prolonged service. Shorter exposures up to 1200°C are possible. Lower temperatures can cause embrittlement. Q: Is Hastelloy X magnetic? A: No, Hastelloy X is non-magnetic, with magnetic permeability close to 1. This makes it useful for certain electronic and high temperature applications. Q: What corrosion environments can Hastelloy X withstand? A: It exhibits excellent corrosion resistance to oxidizing acids, halogens, sulfidation, and stress corrosion cracking environments found in chemical processing. Q: Does Hastelloy X contain cobalt? A: Most grades of Hastelloy X contain 1% or less cobalt. Cobalt-free variants are also available for biomedical applications where cobalt can cause negative health effects. Q: What are the contents of a Hastelloy X powder MSDS? A: It provides composition data, health and reactivity hazards, handling guidance, storage requirements, spill and firefighting procedures, transport information and disposal guidelines that are essential to review before use. Q: Can Hastelloy X powder be 3D printed? A: Yes, Hastelloy X alloy powders can be used in laser and electron beam powder bed fusion additive manufacturing processes. Parameters are optimized to provide dense, crack-free parts. Q: How is Hastelloy X powder made? A: Gas atomization is the common production method where the alloy melt is broken into fine droplets and rapidly solidified into powder. Water atomization is also used either by itself or with gas atomization. Q: What are the alternatives to Hastelloy X? A: Alternatives include Inconel 617, Haynes 230, Inconel 625, and stainless steels like 310 and 330. They offer lower cost but cannot match the oxidation resistance of Hastelloy X in extreme environments.

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Haynes Alloy 188 Powder

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Haynes Alloy188 Powder

Product	Haynes Alloy 188 Powder
CAS No.	N/A
Appearance	Dark Gray Metallic Powder
Purity	≥99%, ≥99.9%, ≥95%(Other purities are also available)
APS	1-5 µM, 10-53 µM (Can be customized), Ask for other available size range.
Ingredient	Fe-Cr-Mo-V-Si
Density	8.9g/cm3
Molecular Weight	N/A
Product Codes	NCZ-DCY-239/25

Haynes Alloy 188 Description:

Haynes Alloy 188 Powder is one of the numerous advanced ceramic materials manufactured by Nanochemazone. Nanochemazone produces too many standard grades when applicable, including Mil Spec (military grade); ACS, Reagent and Technical Grade; Food, Agricultural and Pharmaceutical Grade; Optical Grade, USP and EP/BP (European Pharmacopoeia/British Pharmacopoeia) and follows applicable ASTM testing standards. Typical and custom packaging is available. Additional technical, research and safety (MSDS) information are available. Please request a quote above for more information on lead time and pricing

Haynes Alloy 188 Powder Related Information :

Storage Conditions: Airtight sealed, avoid light and keep dry at room temperature. Please contact us for customization and price inquiry Email: contact@nanochemazone.com Note: We supply different size ranges of Nano and micron as per the client’s requirements and also accept customization in various parameters. Haynes alloy 188 powder Haynes Alloy 188 powder is a nickel-based superalloy renowned for its excellent resistance to high-temperature environments, corrosion, and oxidation. It exhibits remarkable strength, ductility, and creep resistance, making it ideal for applications in extreme conditions. Overview of Haynes Alloy 188 Powder Haynes alloy 188 is a high-performance superalloy exhibiting excellent resistance to oxidation, thermal fatigue and creep at temperatures exceeding 1000°C. The high levels of cobalt, nickel, chromium and tungsten impart exceptional high temperature strength and corrosion resistance. Key characteristics of Haynes 188 powder include: Outstanding high temperature strength and creep resistance Excellent oxidation and corrosion resistance Retains strength during prolonged thermal cycling Resists sulfur and vanadium attack Good fabrication characteristics Available in range of powder sizes and shapes Haynes 188 powder is designed for extremely demanding applications in aviation, chemical processing, power generation, and heat treating industries needing extraordinary performance at high temperatures. Chemical Composition of Haynes Alloy 188 Powder

Element	Weight %
Nickel (Ni)	Balance
Cobalt (Co)	20-25%
Chromium (Cr)	20-25%
Tungsten (W)	12-15%
Iron (Fe)	<3%
Manganese (Mn)	<1.5%
Silicon (Si)	<1%
Carbon (C)	<0.1%

Nickel provides the matrix while cobalt imparts strength. Chromium and tungsten provide excellent oxidation and corrosion resistance. Iron, manganese and silicon are present as impurities. Properties of Haynes Alloy 188 Powder

Property	Value
Density	8.5 g/cm3
Melting Point	1230-1260°C
Thermal Conductivity	9.8 W/m·K
Electrical Resistivity	126 μΩ·cm
Young’s Modulus	205 GPa
Poisson’s Ratio	0.31
Tensile Strength	550-900 MPa
Yield Strength	240-650 MPa
Elongation	25-45%
Fatigue Strength	310 MPa

The properties like strength, ductility and fatigue resistance are maintained at extreme temperatures exceeding 1000°C making it suitable for the most demanding high temperature applications. Production Method for Haynes Alloy 188 Powder Haynes 188 powder is produced using: Gas Atomization – High pressure inert gas jet used to disintegrate molten alloy stream into fine spherical powders. Provides good flow and packing. Water Atomization – High velocity water jet impacts the molten stream to produce fine irregular powders. More economical but higher oxygen pickup. Inert Gas Condensation – Vaporization and controlled condensation of alloying elements in high purity inert gas environment. Yields ultrafine spherical powder. Gas atomization provides the best control over particle size distribution, shape and purity. Applications of Haynes Alloy 188 Powder Typical applications of Haynes 188 powder include: Additive Manufacturing – Used in selective laser melting, electron beam melting to produce complex parts for extreme environments. Thermal Spray Coatings – Deposited using plasma or HVOF spraying to provide wear and corrosion resistance at high temperatures. Brazing Filler – For joining components that must withstand high temperatures during service. Solid Fuel Igniters – Powder metallurgy igniter plugs used in jet engines, land based turbines. Molten Metal Processing – Handling tundishes, conveying components, melt pots used in glass, aluminum and metal industries. Furnace Components – Trays, fixtures, conveyors used in high temperature heat treatment and glass furnaces. Specifications of Haynes Alloy 188 Powder Haynes 188 powder is available in various size ranges, shapes and grades including: Particle Size: From 10-45 microns for AM methods, up to 120 microns for thermal spray processes. Morphology: Spherical, irregular and blended powder shapes. Smooth spherical powder provides better flow. Purity: Ranging from commercial to ultra high purity grades based on stringent chemical analysis. Grades: Conforming to AMS 5758, AMS 5759, AMS 5864 standards tailored for aerospace applications. Surface Area: Powders with low surface area preferred to minimize oxidation. Global Suppliers of Haynes Alloy 188 Powder Some of the major global suppliers are: Carpenter Additive (USA) Sandvik Osprey (UK) Erasteel (France) Edgetech Industries (USA) Special Metals Corp. (USA) Tekna (Canada) These companies produce various grades of Haynes 188 powder tailored for additive manufacturing, thermal spray coatings, and other high temperature applications. Storage and Handling of Haynes Alloy 188 Powder Haynes 188 powder requires careful storage and handling: Should be stored in sealed containers under inert gas to prevent oxidation Avoid accumulation of fine powders to minimize dust explosion risk Wear personal protective equipment when handling fine powder Follow recommended safety practices from manufacturer Proper grounding, ventilation and PPE must be used when handling this reactive alloy powder. Inspection and Testing of Haynes Alloy 188 Powder Key tests carried out for quality control include: Chemical analysis using OES or XRF to ensure composition is within specified limits. Particle size distribution using laser diffraction technique per ASTM B822 standard. Morphology analysis through scanning electron microscopy. Powder flow rate measurement as per ASTM B213 standard using Hall flowmeter. Density measurement using helium pycnometry. Impurity levels tested through ICP-MS. Microstructure characterization by X-ray diffraction. Thorough inspection and testing verifies that the powder meets the chemical, physical and microstructural requirements for the intended application. Comparison Between Haynes 188 and Hastelloy X Powders Haynes 188 and Hastelloy X are two nickel-based alloy powders compared:

Parameter	Haynes 188	Hastelloy X
Base element	Nickel	Nickel
Cr content	22-25%	22-25%
Mo content	No molybdenum	8-10%
Oxidation resistance	Excellent up to 1204°C	Excellent up to 1150°C
Cost	Higher	Lower
Strength	Lower	Higher
Workability	Excellent	Moderate
Applications	Coatings, braze filler	Aerospace components, springs

Haynes 188 offers better workability while Hastelloy X has higher strength. Haynes 188 resists oxidation at extremely high temperatures. Haynes Alloy 188 Powder FAQs Q: How is Haynes alloy 188 powder produced? A: Haynes 188 powder is commercially produced using gas atomization, water atomization, and inert gas condensation techniques. Gas atomization offers the best control over particle characteristics. Q: What are the main applications for Haynes 188 powder? A: Key applications are additive manufacturing, thermal spray coatings, brazing filler material, powder metallurgy igniter plugs, and high temperature furnace components needing extraordinary oxidation and corrosion resistance. Q: What is the recommended powder size for AM or thermal spray? A: For additive manufacturing, the ideal size range is 15-45 microns. For thermal spray coatings, a coarser powder up to 120 microns is preferred. Q: Does Haynes 188 powder require special handling precautions? A: Yes, it is recommended to handle this reactive alloy powder carefully under inert atmosphere using proper grounding, ventilation and PPE. Q: Where can I purchase Haynes 188 powder suitable for aerospace applications? A: High purity Haynes 188 powder meeting aerospace standards can be sourced from leading manufacturers like Nanochemazone.

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Hexagon Boron Nitride Powder

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Product Name: Hexagon Boron Nitride Powder

Product	Hexagon Boron Nitride Powder
CAS No.	10043-11-5
Appearance	Powder
Purity	99.9%
APS	1 – 5 microns (can be customized)
Ingredient	BN
Product Code	NCZ-AE-201

RELATED INFORMATION Storage Conditions: Airtight sealed, avoid light, and keep dry at room temperature. Please email us for the customization. Email: contact@nanochemazone.com

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Hexagonal Boron Nitride (H-BN) on Copper Foil

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Hexagonal Boron Nitride (H-BN) on Copper Foil

Transparency	> 97%
hBN Coverage	100% with sporadic adlayers
Raman Peak	1370 /cm^-1
Bandgap	5.97 eV
Grain size	>4 μm
Copper Foil	25 μm thick

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Hexagonal Boron Nitride (H-BN) on Si/SiO2

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Hexagonal Boron Nitride (H-BN) on Si/SiO2

Product Name	Monolayer h-BN
Transparency	> 97%
hBN Coverage	100% with sporadic adlayers
Raman Peak	1370 /cm^-1
Bandgap	5.97 eV
Grain size	>4 μm

Si/SiO2 Substrate
Type/Doing	P/B
Wafer Thickness	500 +/- 50 μm
Oxide Thickness	300 nm
Resistivity	1-10 (Ω -cm)
Orientation	<1-0-0>
Growth Method	CZ
Metal Impurities	1.00e¹⁰ – 5.00e¹⁰ (at/cm²)

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Hexahydroxyplatinic Acid Powder

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Hexahydroxyplatinic Acid Powder

Product	Hexahydroxyplatinic Acid Powder
CAS No.	51850-20-5
Appearance	Light Yellow Crystalline Powder
Purity	≥99%, ≥99.9%, ≥95%(Other purities are also available)
APS	1-5 µM, 10-53 µM (Can be customized), Ask for other available size range.
Ingredient	H2Pt(OH)6
Density	N/A
Molecular Weight	298.997g/mol
Product Code	NCZ-MNO-362/25

Hexahydroxyplatinic Acid Description:

Hexahydroxyplatinic Acid Powder is one of the numerous advanced ceramic materials manufactured by Nanochemazone. Nanochemazone produces too many standard grades when applicable, including Mil Spec (military grade); ACS, Reagent and Technical Grade; Food, Agricultural and Pharmaceutical Grade; Optical Grade, USP and EP/BP (European Pharmacopoeia/British Pharmacopoeia) and follows applicable ASTM testing standards. Typical and custom packaging is available. Additional technical, research and safety (MSDS) information are available. Please request a quote above for more information on lead time and pricing.

Hexahydroxyplatinic Acid Powder Related Information:

Catalog No.	NCZ-MNO-362/25
Purity	98%
CAS Number	51850-20-5
Appearance	Light yellow crystalline powder
Molecular Formula	H2Pt(OH)6

Hexahydroxyplatinic Acid Powder Description Hexahydroxyplatinic acid powder is a Platinum compound. Hexahydroxyplatinic Acid Powder Specifications

CAS Number	51850-20-5
Molecular formula	H2Pt(OH)6
Molecular weight	298.997
Appearance	Light yellow crystalline powder
Theoretical metal content:	65%
Sensitivity	Moisture Sensitive
Solubility	Insoluble

Hexahydroxyplatinic Acid Powder Applications research Hexahydroxyplatinic Acid Powder is used as a precursor to producing platinum dioxide (II), a catalyst for hydrogenation and hydrogenolysis of carbonyl group or C-Cl linkages in acyl chlorides. It also acts as a precursor to producing other platinum compounds. Safety information of Hexahydroxyplatinic Acid Powder

Symbol	GHS07
Signal word	Warning
Hazard statements	H315-H319-H332-H335
Precautionary statements	P261-P305 + P351 + P338
Personal protective equipment	Dust mask type N95 (US), Eye shields, Gloves
RIDADR	NONH for all modes of transport
WGK Germany	3

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Hexarhodium(0) Hexadecacarbonyl Powder

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Hexarhodium(0) Hexadecacarbonyl Powder

Product	Hexarhodium(0) Hexadecacarbonyl Powder
CAS No.	28407-51-4
Appearance	Black Powder
Purity	≥99%, ≥99.9%, ≥95% (Other purities are also available)
APS	1-5 µM, 10-53 µM (Can be customized), Ask for other available size range.
Ingredient	Rh6(CO)16
Density	N/A
Molecular Weight	1065.59g/mol
Product Code	NCZ-MNO-349/25

Hexarhodium(0) Hexadecacarbonyl Description:

Hexarhodium(0) Hexadecacarbonyl Powder is one of the numerous advanced ceramic materials manufactured by Nanochemazone. Nanochemazone produces too many standard grades when applicable, including Mil Spec (military grade); ACS, Reagent and Technical Grade; Food, Agricultural and Pharmaceutical Grade; Optical Grade, USP and EP/BP (European Pharmacopoeia/British Pharmacopoeia) and follows applicable ASTM testing standards. Typical and custom packaging is available. Additional technical, research and safety (MSDS) information are available. Please request a quote above for more information on lead time and pricing.

Hexarhodium(0) Hexadecacarbonyl Powder Related Information:

Catalog No.	NCZ-MNO-349/25
Purity	99.0%
CAS Number	28407-51-4
Appearance	Black powder
Molecular Formula	Rh6(CO)16
Theoretical Metal Content	57.9%

Hexarhodium(0) Hexadecacarbonyl Powder Description Hexarhodium Hexadecacarbonyl is a commonly used organometallic catalyst. The applications of Hexarhodium(0) Hexadecacarbonyl Powder include the hydroformylation of olefins. Hexarhodium(0) Hexadecacarbonyl Powder Specifications

CAS Number	28407-51-4
Molecular Formula	Rh6(CO)16
Molecular Weight	1065.59
Appearance	Black powder
Storage	Store at RT

Hexarhodium(0) Hexadecacarbonyl Powder Applications Hexarhodium(0) Hexadecacarbonyl Powder can be used as a catalyst for hydrogenation of alkenes, hydroformylations ofalkenes; reducing agent for aldehydes, ketones, and nitro groups; catalyst for carbenoid reactions of diazo compounds. Hexarhodium(0) Hexadecacarbonyl Powder Safety Information

Symbol	GHS07
Signal Word	Warning
Hazard Statements	H302 + H312 + H332
Precautionary Statements	P280
Personal Protective Equipment	dust mask type N95 (US), Eye shields, Gloves
RIDADR	NONH for all modes of transport
WGK Germany	3

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High Activity Platinum on Carbon Catalyst Powder

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High Activity Platinum on Carbon Catalyst Powder

Product	High Activity Platinum on Carbon Catalyst Powder
CAS No.	7440-06-4
Appearance	Black Powder
Purity	≥99%, ≥99.9%, ≥95% (Other purities are also available)
APS	1-5 µM, 10-53 µM (Can be customized), Ask for other available size range.
Ingredient	Pt/C
Density	N/A
Molecular Weight	N/A
Product Code	NCZ-MNO-358/25

High Activity Platinum on Carbon Catalyst Description:

High Activity Platinum on Carbon Catalyst Powder is one of the numerous advanced ceramic materials manufactured by Nanochemazone. Nanochemazone produces too many standard grades when applicable, including Mil Spec (military grade); ACS, Reagent and Technical Grade; Food, Agricultural and Pharmaceutical Grade; Optical Grade, USP and EP/BP (European Pharmacopoeia/British Pharmacopoeia) and follows applicable ASTM testing standards. Typical and custom packaging is available. Additional technical, research and safety (MSDS) information are available. Please request a quote above for more information on lead time and pricing.

High Activity Platinum on Carbon Catalyst Powder Related Information:

Catalog No.	NCZ-MNO-358/25
Compositions	Pt/C
Appearance	black powder
Electrochemically Active Area (m2/g)	60-70
Max Working Temp. (℃)	95

High Activity Platinum on Carbon Catalyst Description High Activity Platinum on Carbon Catalyst is a Pt-based electrocatalyst based on carbon black, which has the advantages of small active metal particle size, uniform particle size distribution, high electrochemical active area (ECSA), and mass-specific activity (MA), and long life. High Activity Platinum on Carbon Catalyst Specifications

Chemical Composition	Pt/C
Oxygen Reduction Mass Activity Ratio (A/mgpt)	0.2
Electrochemically Active Area (m2/g)	60-70
Max Working Temp. (℃)	95

High Activity Platinum on Carbon Catalyst Applications High Activity Platinum on Carbon Catalyst is mainly used in hydrogen fuel cells and electrolysis of water to produce hydrogen. High Activity Platinum on Carbon Catalyst Packaging Our High Activity Platinum on Carbon Catalyst is carefully handled during storage and transportation to preserve the quality of our product in its original condition.

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Highly Pure Graphene Nanoplatelets Powder

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High Purity Graphene Nanoplatelets

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Graphene Nanoplatelets Powder

MF:	C
Chemical Name:	Graphene Nanoplatelets
Purity:	> 99.99%
APS:	5-10 µm, 20-50 layers (Size Customization possible)
Form:	Nanopowder
Product Number:	#NCZ3001-19
CAS Number	99685-96-8

Please contact us for customization and price inquiry.

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High-Alumina Brick Powder

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High-Alumina Brick Powder

Product	High-Alumina Brick Powder
CAS No.	1344-28-1
Appearance	White or Gray Powder
Purity&nbsp	≥99%, ≥99.9%, ≥95% (Other purities are also available)
APS&nbsp&nbsp	1-5 µM, 10-53 µM (Can be customized), Ask for other available size range.
Ingredient	Al2O3
Density	2.0 to 4.1g/cm3
Molecular Weight	101.948g/mol
Product Codes	NCZ-MNO-117/25

High-Alumina Brick Description:

High-Alumina Brick Powder is one of the numerous advanced ceramic materials manufactured by Nanochemazone. Nanochemazone produces too many standard grades when applicable, including Mil Spec (military grade); ACS, Reagent and Technical Grade; Food, Agricultural and Pharmaceutical Grade; Optical Grade, USP and EP/BP (European Pharmacopoeia/British Pharmacopoeia) and follows applicable ASTM testing standards. Typical and custom packaging is available. Additional technical, research and safety (MSDS) information are available. Please request a quote above for more information on lead time and pricing.

High-Alumina Brick Powder Related Information :

Catalog No.	NCZ-MNO-117/25
Material	Alumina
Color	White or gray
Density	≥3g/cm3
Water absorption	≤5%

High-Alumina Firebrick is a brick body that can withstand combustion and high temperature. Its refractoriness is around 1700 °C. It provides high-quality High-Aluminum brick to meet your needs. High-Alumina Brick Description The High-Alumina brick has high sintering temperature, high refractoriness under load, high compressive strength, high-temperature flexural strength, and low thermal expansion efficiency. High Alumina Bricks are produced with selected bauxite chamotte as the main raw material, fired at 1450-1470 °C by the advanced process with strict quality control. High-Alumina Brick Applications High-Alumina Firebricks are mainly used in the construction of various industrial furnaces, such as masonry iron-making furnaces, steelmaking furnaces, coke ovens, glass furnaces, cement kilns, steam boilers, various heat treatment furnaces, heating furnaces, etc., as well as other high-temperature furnaces. Different types of refractory bricks should not be mixed. When firebricks are built, the same type of refractory clay as refractory bricks should be used as cement. High-Alumina Brick Specifications

type	HAB-75	HAB-65	HAB-55
Al2O3≥ %	75	65	55
Fe2O3＜ %	2.5	2.4	2.6
bulk density g/cm³	2.5	2.5	2.3
comprehension stress Mpa	70	60	50
refractoriness under load °C	1510	1460	1420
refractory temperature °C	1790	1770	1770
porosity %	22	23	24
PLC %	-0.3	-0.4	-0.4

High-Alumina Brick Packaging Our high-Alumina bricks are carefully handled to minimize damage during storage and transportation and to preserve the quality of our products in their original condition.

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Highly Conducting Silver Nanowire

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Product	Highly Conducting Silver Nanowire
Formula	Ag
Stock No.	NCZNW116-19
Melting Point	1234.93 K
Boiling point	2,435 K
Density	10.49 g/cm³
Diameter	25 nm (customization available)
Length	10 µm (customization available)

Please contact us for customization and price inquiry. Note: We supply different size ranges of Silver Nanowires as per the client’s requirements and also accept customization in various parameters.

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Holmium (Ho) Micron Powder

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Holmium (Ho) Micron Powder, Purity: 99.5 %, Size: 325 mesh Holmium (Ho) Micron Powder Purity: 99.5 %, Size: 325 mesh Technical Properties:

Product Number	NCZ-RE-106-19
Purity	99.5 %
Particle Size	325 mesh
Density	8.795 g/cc
Melting Point	1474 °C
Boiling Point	2695 °C
Electrical Resistivity	87.0 micro ohm-cm @ 25 °C

Note: We can manufacture and supply different particle sizes (Nano size range, Micron, Submicron, and different Mesh size) products of Alloy powders (Multi-Element, Multi-Element Oxide and Mixture of Rare Earth Elements) according to client’s requirements. Kindly ask for the customization in size and Element ratio composition.

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Holmium Acetate Powder

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Holmium Acetate Powder

Product	Holmium Acetate Powder
CAS No.	312619-49-1
Appearance	Light Yellow Powder
Purity	≥99%, ≥99.9%, ≥95%(Other purities are also available)
APS	1-5 µM, 10-53 µM (Can be customized), Ask for other available size range.
Ingredient	Ho(CH3COO)3
Density	N/A
Molecular Weight	342.07g/mol
Product Code	NCZ-CAS-173/25

Holmium Acetate Description:

Holmium Acetate Powder is one of the numerous advanced ceramic materials manufactured by Nanochemazone. Nanochemazone produces too many standard grades when applicable, including Mil Spec (military grade); ACS, Reagent and Technical Grade; Food, Agricultural and Pharmaceutical Grade; Optical Grade, USP and EP/BP (European Pharmacopoeia/British Pharmacopoeia) and follows applicable ASTM testing standards. Typical and custom packaging is available. Additional technical, research and safety (MSDS) information are available. Please request a quote above for more information on lead time and pricing.

Holmium Acetate Powder Related Information:

Compound Formula	C6H9HoO6
Molecular Weight	342.07
Appearance	Light Yellow
Melting Point	N/A
Boiling Point	N/A
Density	N/A
Solubility in H2O	N/A
Exact Mass	341.97 g/mol
Monoisotopic Mass	341.97 g/mol

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Holmium Acetate Solution Powder

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Holmium Acetate Solution Powder

Product	Holmium Acetate Solution Powder
CAS No.	312619-49-1
Appearance	Pink Powder
Purity	≥99%, ≥99.9%, ≥95%(Other purities are also available)
APS	1-5 µM, 10-53 µM (Can be customized), Ask for other available size range.
Ingredient	Ho(CH3COO)3
Density	N/A
Molecular Weight	342.07g/mol
Product Code	NCZ-CAS-174/25

Holmium Acetate Solution Description:

Holmium Acetate Solution Powder is one of the numerous advanced ceramic materials manufactured by Nanochemazone. Nanochemazone produces too many standard grades when applicable, including Mil Spec (military grade); ACS, Reagent and Technical Grade; Food, Agricultural and Pharmaceutical Grade; Optical Grade, USP and EP/BP (European Pharmacopoeia/British Pharmacopoeia) and follows applicable ASTM testing standards. Typical and custom packaging is available. Additional technical, research and safety (MSDS) information are available. Please request a quote above for more information on lead time and pricing.

Holmium Acetate Solution Powder Related Information:

Compound Formula	C6H9HoO6
Molecular Weight	342.07
Appearance	liquid
Melting Point	N/A
Boiling Point	N/A
Density	N/A
Solubility in H2O	N/A
Exact Mass	341.97 g/mol
Monoisotopic Mass	341.97 g/mol

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Holmium Chloride hexahydrate Powder

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Product Name: Holmium Chloride hexahydrate Powder

Product	Holmium Chloride hexahydrate
CAS No.	14914-84-2
Appearance	Yellow Powder
Purity	99.9%
APS	1 – 5 Microns (Can be customized)
Ingredient	HoCl₃•6H₂O
Product Code	NCZ-NSC-323/20

Holmium Chloride hexahydrate Powder Description:

Holmium chloride hexahydrate is used as a laboratory reagent and also used in proteomics research optical glasses, structural ceramics, catalysts, Holmium Chloride hexahydrate is used electrical components, and photo-optical material.

Holmium Chloride hexahydrate Powder Related Information

Storage Conditions: Airtight sealed, avoid light, and keep dry at room temperature. Please contact us for customization and price inquiry Email: contact@nanochemazone.com Note: We supply different size ranges of Nano and micron as per the client’s requirements and also accept customization in various parameters.

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Holmium Metal Powder

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Product Name: Holmium Metal Powder

Product	Holmium Metal Powder
CAS No.	7440-60-0
Appearance	White Powder
Purity	99.9%
APS	1 – 5 Microns (Can be customized)
Ingredient	Ho
Product Code	NCZ-NSC-322/20

Holmium Metal Powder Description :

Holmium Metal Powder has the highest magnetic permeability of any element and therefore is used for the polepieces of the strongest static magnets.

Because holmium strongly absorbs neutrons, It is also used as a burnable poison in nuclear reactors.

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Holmium Nitrate Pentahydrate Powder

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Product Name: Holmium Nitrate Pentahydrate Powder

Product	Holmium Nitrate Pentahydrate Powder
CAS No.	14483-18-2
Appearance	Yellow Powder
Purity	99.9%
APS	1 – 5 Microns (Can be customized)
Ingredient	Ho(NO₃)₃•5H₂O
Product Code	NCZ-NSC-324/20

Holmium Nitrate Pentahydrate Powder Description:

Holmium Nitrate Pentahydrate is used to prepare the holmium-beta-cyclodextrin complex by reacting with beta-cyclodextrin, which posses potential pharmacological applications.

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Holmium Oxide (Ho2O3) Micron Powder

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Holmium Oxide (Ho2O3) Micron Powder, Purity: 99.99%, Size: 325 mesh

Holmium Oxide (Ho2O3) Micron Powder

Purity: 99.99 %, Size: 325 mesh

Technical Properties:

Product Number	NCZ-RE-121-19
PURITY	99.99 %
COLOR	Yellow, Orange Red

Note: We can manufacture and supply different particle sizes (Nano size range, Micron, Submicron, and different Mesh size) products of Alloy powders (Multi-Element, Multi-Element Oxide and Mixture of Rare Earth Elements) according to client’s requirements. Kindly ask for the customization in size and Element ratio composition.

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Holmium Oxide Powder

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Product Name: Holmium Oxide Powder

Product	Holmium Oxide Powder
CAS No.	12055-62-8
Appearance	Powder
Purity	99.9%
APS	1 – 5 microns (can be customized)
Ingredient	Ho2O3
Product Code	NCZ-AE-200

RELATED INFORMATION Storage Conditions: Airtight sealed, avoid light, and keep dry at room temperature. Please email us for the customization. Email: contact@nanochemazone.com

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Holmium(III) Acetate Monohydrate Powder

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Holmium(III) Acetate Monohydrate Powder

Product	Holmium(III) Acetate Monohydrate Powder
CAS No.	25519-09-9
Appearance	Peach Powder
Purity	≥99%, ≥99.9%, ≥95%(Other purities are also available)
APS	1-5 µM, 10-53 µM (Can be customized), Ask for other available size range.
Ingredient	Ho(CH3COO)3.H2O
Density	N/A
Molecular Weight	360.08g/mol
Product Code	NCZ-CAS-175/25

Holmium(III) Acetate Monohydrate Description:

Holmium(III) Acetate Monohydrate Powder is one of the numerous advanced ceramic materials manufactured by Nanochemazone. Nanochemazone produces too many standard grades when applicable, including Mil Spec (military grade); ACS, Reagent and Technical Grade; Food, Agricultural and Pharmaceutical Grade; Optical Grade, USP and EP/BP (European Pharmacopoeia/British Pharmacopoeia) and follows applicable ASTM testing standards. Typical and custom packaging is available. Additional technical, research and safety (MSDS) information are available. Please request a quote above for more information on lead time and pricing.

Holmium(III) Acetate Monohydrate Powder Related Information:

Compound Formula	C6H11HoO7
Molecular Weight	360.08
Appearance	Peach powder
Melting Point	N/A
Boiling Point	N/A
Density	N/A
Solubility in H2O	N/A
Exact Mass	359.9808 g/mol
Monoisotopic Mass	359.9808 g/mol
Charge	0

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Hydrofluoric Acid

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Product Name: Hydrofluoric Acid

Product	Hydrofluoric Acid
CAS No.	7664-39-3
Form	Liquid
Purity	≥ 99 %
APS	Not Available
Ingredient	Not Available
Product Code	NCZ-MS-121

RELATED INFORMATION Storage Conditions: Airtight sealed, avoid light, and keep dry at room temperature. Please email us for the customization. Email: contact@nanochemazone.com

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Hydroxy apatite Nanowires | Nanochemazone®

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Hydroxyapatite Nanowire

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Product	Hydroxyapatite Nanowire
Formula	Ca₅(PO₄)₃(OH)
Stock No.	NCZNW105-19
Formula Mass	502.31g/mol
Crystal System	Hexagonal
Specific Gravity	3.14-3.21
Diameter	40 nm (customization available)
length	20 µm (customization available)

Please contact us for customization and price inquiry. Note: We supply different size ranges of Hydroxyapatite Nanowires as per the client’s requirements and also accept customization in various parameters.

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Hydroxylated Graphene Quantum Dots

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Hydroxylated Graphene Quantum Dots

CAS Number	7440-40-0
Product Number	NCZC3002
Concentration	1mg/mL to 20 mg/mL (in stock), Concentration Customization is Possible
Carrier	Water, Ethanol, IPA, NMP, Toluene, Methanol, Dispersion Customization is Possible
APS	5-10 nm (Customization is Possible)
Package Size	1-100 mL (Customization is Possible)

CHARACTERIZATIONS

Composition:	Hydroxylated Graphene Quantum Dots
Appearance:	Colorless solution
PL peak:	480 nm (reference only, the actual value may vary)
Particle Size:	＜10 nm
Concentration:	1 mg/ml (available up to 20mg/ml)
Solution:	Water, a mixture of water and ethylene glycol (customization possible)
Purity:	> 99.9%

Please contact us for customization and price inquiry.

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IN738LC Powder

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IN738LC Powder

Product	IN738LC Powder
CAS No.	N/A
Appearance	Metallic Gray Powder
Purity	≥99%, ≥99.9%, ≥95%(Other purities are also available)
APS	1-5 µM, 10-53 µM (Can be customized), Ask for other available size range.
Ingredient	Ni-16Cr-8.5Co-2.4Al-3.4Ti-1.75Mo-1.75w-0.9Nb-0.6Zr-0.1C
Density	8.11g/cm3
Molecular Weight	N/A
Product Codes	NCZ-DCY-203/25

INC738LC Description:

INC738LC Powder is one of the numerous advanced ceramic materials manufactured by Nanochemazone. Nanochemazone produces too many standard grades when applicable, including Mil Spec (military grade); ACS, Reagent and Technical Grade; Food, Agricultural and Pharmaceutical Grade; Optical Grade, USP and EP/BP (European Pharmacopoeia/British Pharmacopoeia) and follows applicable ASTM testing standards. Typical and custom packaging is available. Additional technical, research and safety (MSDS) information are available. Please request a quote above for more information on lead time and pricing

INC738LC Powder Related Information :

Metal Powder	Size	Quantity	Price/kg	Size	Quantity	Price/kg
Inconel 738LC	15-45μm	1KG	$137.9	20-60μm	1KG	$134
		10KG	$109.8		10KG	$109
		100KG	$99.7		100KG	$98

IN738LC is a nickel-based superalloy powder widely used in additive manufacturing, particularly for applications requiring high-temperature strength and corrosion resistance. This advanced material has gained significant traction in industries such as aerospace, energy, and automotive due to its exceptional properties and the ability to produce complex geometries through 3D printing processes like selective laser melting (SLM) and electron beam melting (EBM). In this article, we will delve into the intricacies of IN738LC powder, exploring its composition, characteristics, benefits, applications, printing processes, and key suppliers.

Alloy	Nominal Composition (wt%)
IN738LC	Ni – 16Cr – 8.5Co – 3.4Al – 3.4Ti – 1.7Mo – 2.6W – 1.7Ta – 0.9Nb – 0.05C – 0.03Zr – 0.001B

Characteristics of IN738LC Powder

Property	Value
Density	8.19 g/cm³
Melting Range	1260-1335°C
Yield Strength (at 650°C)	>758 MPa
Tensile Strength (at 650°C)	>1035 MPa
Elongation (at 650°C)	>12%
Grain Size	Fine-grained
Gamma Prime Phase	High volume fraction

IN738LC powder exhibits exceptional high-temperature strength, creep resistance, and oxidation resistance due to its unique composition and microstructure. The presence of aluminum, titanium, and refractory elements like tungsten and tantalum contributes to the formation of a high volume fraction of gamma prime (γ’) precipitates, which are responsible for its superior mechanical properties at elevated temperatures. Benefits of Using IN738LC Powder for 3D Printing Additive manufacturing with IN738LC powder offers numerous benefits over traditional manufacturing methods, making it an attractive choice for various industries. Let’s explore some of the key advantages: Design Flexibility: 3D printing allows for the production of complex geometries and intricate internal structures that would be challenging or impossible to manufacture using conventional methods. This design freedom enables the creation of optimized components with improved functionality and performance. Weight Reduction: By leveraging the design flexibility of additive manufacturing, engineers can produce lightweight yet robust components with optimized topologies, resulting in significant weight savings, particularly in aerospace and automotive applications. Rapid Prototyping: The ability to quickly produce prototypes and functional parts from IN738LC powder accelerates the product development cycle, enabling faster iterations and reducing time-to-market. Material Efficiency: Additive manufacturing processes like SLM and EBM have higher material utilization rates compared to subtractive manufacturing methods, leading to less waste and improved resource efficiency. Customization: 3D printing enables the production of customized components tailored to specific requirements, making it ideal for applications with low-volume or unique demands. Repair and Remanufacturing: IN738LC powder can be used to repair or remanufacture worn or damaged components, extending their service life and reducing replacement costs. Applications of IN738LC Powder in 3D Printing

Application	Industry	Examples
Turbine Components	Aerospace, Energy	Blades, Vanes, Nozzles
Automotive Components	Automotive	Turbochargers, Exhaust Manifolds
Tooling and Molds	Manufacturing	Injection Molds, Die Casting Molds
Heat Exchangers	Energy, Chemical	High-Temperature Recuperators
Medical Implants	Healthcare	Orthopedic Implants, Dental Restorations

The exceptional high-temperature properties and corrosion resistance of IN738LC make it suitable for a wide range of applications across various industries. In the aerospace and energy sectors, this superalloy is widely used for producing turbine components, such as blades, vanes, and nozzles, which are subject to extreme temperatures and high stresses. The automotive industry also benefits from IN738LC powder in the manufacturing of turbochargers and exhaust manifolds. Additionally, IN738LC powder finds applications in tooling and mold making, where its high strength and wear resistance are invaluable. Heat exchangers and recuperators in the energy and chemical industries also utilize this material due to its ability to withstand elevated temperatures and corrosive environments. Moreover, the biocompatibility of IN738LC makes it a promising candidate for medical implants and dental restorations. 3D Printing Processes for IN738LC Powder Additive manufacturing processes compatible with IN738LC powder include selective laser melting (SLM) and electron beam melting (EBM). These powder bed fusion techniques offer excellent control over the microstructure and properties of the final component. Selective Laser Melting (SLM): In the SLM process, a high-powered laser selectively melts and fuses the IN738LC powder layer by layer, according to the 3D model data. The build chamber is typically filled with an inert gas, such as argon or nitrogen, to prevent oxidation and maintain the desired material properties. Electron Beam Melting (EBM): EBM utilizes a focused electron beam to selectively melt the IN738LC powder in a vacuum environment. This process allows for higher build rates and can produce parts with excellent mechanical properties and reduced residual stresses. Both SLM and EBM processes require careful control of process parameters, such as laser or electron beam power, scan speed, hatch spacing, and layer thickness, to ensure optimal densification, microstructure, and mechanical properties of the final component. To achieve the desired properties, post-processing steps like stress relief heat treatments, hot isostatic pressing (HIP), and surface finishing may be necessary, depending on the application requirements.

Powder Specifications

Particle Size Distribution: 15-53 μm

Flowability: Excellent

Sphericity: High

Apparent Density: 4.2-4.6 g/cm³

Standards: AMS 5832, AMS 5385

Typical Grades

IN738LC – Standard Grade

IN738LC-LG – Low Gauge Grade

IN738LC-HG – High Gauge Grade

Pros and Cons of Using IN738LC Powder for 3D Printing

Pros	Cons
Excellent high-temperature strength and creep resistance	Higher material cost compared to some other alloys
Superior oxidation and corrosion resistance	Potential for cracking and distortion during printing
Ability to produce complex geometries	Strict process control required for optimal properties
Lightweight and high strength-to-weight ratio	Limited availability of qualified suppliers

Advantages of IN738LC Powder for 3D Printing When compared to traditional manufacturing methods, additive manufacturing with IN738LC powder offers several distinct advantages: Design Optimization: The ability to produce complex geometries and internal features enables the design of components with optimized topologies, leading to weight reduction and improved performance. For instance, in the aerospace industry, lightweight yet strong turbine blades can be created, resulting in increased fuel efficiency and reduced emissions. Rapid Prototyping and Iteration: The additive manufacturing process allows for rapid prototyping and iterative design cycles, significantly shortening the product development timeline. This advantage is particularly valuable in industries with stringent testing and certification requirements, such as aerospace and automotive. Customization and Personalization: 3D printing with IN738LC powder enables the production of customized or patient-specific components, catering to unique requirements in fields like medical implants, tooling, and specialized industrial applications. Material Efficiency and Waste Reduction: Additive manufacturing processes have higher material utilization rates compared to subtractive methods, resulting in less waste and improved resource efficiency. This not only reduces material costs but also contributes to a more sustainable manufacturing approach. Repair and Remanufacturing: IN738LC powder can be used to repair or remanufacture worn or damaged components, extending their service life and reducing replacement costs. This capability is particularly beneficial in industries with high-value assets, such as aerospace and energy. While additive manufacturing with IN738LC powder offers numerous advantages, it is essential to consider potential limitations and challenges. Process control, post-processing requirements, and the availability of qualified suppliers can impact the overall feasibility and cost-effectiveness of using this material for specific applications. Limitations of IN738LC Powder for 3D Printing Despite its numerous benefits, using IN738LC powder for 3D printing also presents some limitations and challenges: Higher Material Cost: Nickel-based superalloys like IN738LC are generally more expensive compared to some other alloys used in additive manufacturing, which can increase the overall cost of production. Strict Process Control: Achieving optimal mechanical properties and part quality with IN738LC powder requires precise control over various process parameters, such as laser or electron beam power, scan speed, hatch spacing, and layer thickness. Deviations from the optimal parameters can lead to defects or suboptimal performance. Potential for Cracking and Distortion: Due to the high thermal gradients and residual stresses involved in the additive manufacturing process, IN738LC components can be susceptible to cracking and distortion. Careful design, process optimization, and post-processing techniques like stress relief heat treatments and hot isostatic pressing (HIP) may be necessary to mitigate these issues. Limited Availability of Qualified Suppliers: While several suppliers offer IN738LC powder, the number of qualified and experienced suppliers may be limited compared to more widely used materials. This can impact the availability, lead times, and pricing of the powder. Post-Processing Requirements: Depending on the application and performance requirements, post-processing steps like hot isostatic pressing (HIP), heat treatments, and surface finishing may be necessary to achieve the desired mechanical properties and surface quality. These additional steps can increase the overall cost and lead time. It is crucial to carefully evaluate the specific requirements of your application, weighing the advantages and limitations of using IN738LC powder for 3D printing. Collaboration with experienced suppliers, process optimization, and a thorough understanding of the material’s behavior during additive manufacturing are essential for successful implementation.

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IN738LC Powder

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IN738LC Powder

Product	INC738LC Powder
CAS No.	N/A
Appearance	Gray or Metallic Silver Powder
Purity	≥99%, ≥99.9%, ≥95%(Other purities are also available)
APS	1-5 µM, 10-53 µM (Can be customized), Ask for other available size range.
Ingredient	Ni-16Cr-8.5Co-2.4Al-3.4Ti-1.75Mo-1.75w-0.9Nb-0.6Zr-0.1C
Density	8.19g/cm3
Molecular Weight	N/A
Product Codes	NCZ-DCY-278/25

IN738LC Description:

IN738LC Powder Related Information :

Alloy	Nominal Composition (wt%)
IN738LC	Ni – 16Cr – 8.5Co – 3.4Al – 3.4Ti – 1.7Mo – 2.6W – 1.7Ta – 0.9Nb – 0.05C – 0.03Zr – 0.001B

Characteristics of IN738LC Powder

Property	Value
Density	8.19 g/cm³
Melting Range	1260-1335°C
Yield Strength (at 650°C)	>758 MPa
Tensile Strength (at 650°C)	>1035 MPa
Elongation (at 650°C)	>12%
Grain Size	Fine-grained
Gamma Prime Phase	High volume fraction

Application	Industry	Examples
Turbine Components	Aerospace, Energy	Blades, Vanes, Nozzles
Automotive Components	Automotive	Turbochargers, Exhaust Manifolds
Tooling and Molds	Manufacturing	Injection Molds, Die Casting Molds
Heat Exchangers	Energy, Chemical	High-Temperature Recuperators
Medical Implants	Healthcare	Orthopedic Implants, Dental Restorations

Powder Specifications

Particle Size Distribution: 15-53 μm

Flowability: Excellent

Sphericity: High

Apparent Density: 4.2-4.6 g/cm³

Standards: AMS 5832, AMS 5385

Typical Grades

IN738LC – Standard Grade

IN738LC-LG – Low Gauge Grade

IN738LC-HG – High Gauge Grade

Pros and Cons of Using IN738LC Powder for 3D Printing

Pros	Cons
Excellent high-temperature strength and creep resistance	Higher material cost compared to some other alloys
Superior oxidation and corrosion resistance	Potential for cracking and distortion during printing
Ability to produce complex geometries	Strict process control required for optimal properties
Lightweight and high strength-to-weight ratio	Limited availability of qualified suppliers

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IN939 Powder

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IN939 Powder

Product	IN939 Powder
CAS No.	2634-33-5
Appearance	Yellowish Powder
Purity	≥99%, ≥99.9%, ≥95%(Other purities are also available)
APS	1-5 µM, 10-53 µM (Can be customized), Ask for other available size range.
Ingredient	C6H6N6O6
Density	1.85g/cm3
Molecular Weight	258.15g/mol
Product Codes	NCZ-DCY-205/25

IN939 Description:

IN939 Powder is one of the numerous advanced ceramic materials manufactured by Nanochemazone. Nanochemazone produces too many standard grades when applicable, including Mil Spec (military grade); ACS, Reagent and Technical Grade; Food, Agricultural and Pharmaceutical Grade; Optical Grade, USP and EP/BP (European Pharmacopoeia/British Pharmacopoeia) and follows applicable ASTM testing standards. Typical and custom packaging is available. Additional technical, research and safety (MSDS) information are available. Please request a quote above for more information on lead time and pricing

IN939 Powder Related Information :

Storage Conditions: Airtight sealed, avoid light and keep dry at room temperature. Please contact us for customization and price inquiry Email: contact@nanochemazone.com Note: We supply different size ranges of Nano and micron as per the client’s requirements and also accept customization in various parameters. Best IN939 Powder for 3D Printing in 2024 IN939 powder is a nickel-based superalloy that exhibits exceptional mechanical properties and high resistance to corrosion and oxidation. It is primarily composed of nickel, chromium, cobalt, molybdenum, and tantalum. This composition gives IN939 powder its remarkable strength, heat resistance, and stability at elevated temperatures. Overview of IN939 Powder for 3D Printing IN939 is a high-performance nickel-based superalloy powder designed for additive manufacturing of critical components needing exceptional mechanical properties at high temperatures. This article provides a comprehensive guide to IN939 powder for 3D printing applications across aerospace, automotive, energy and industrial sectors. Key aspects covered include IN939 composition, properties, print parameters, applications, specifications, suppliers, handling, inspection, comparisons to alternatives, advantages and limitations, and frequently asked questions. Quantitative data is presented in easy-to-reference tables. Composition of IN939 Powder IN939 has a complex precipitation hardening alloy composition:

Element	Weight %	Purpose
Nickel	Balance	Principal matrix element
Chromium	15 – 18	Oxidation resistance
Aluminum	3.8 – 4.8	Precipitation hardening
Titanium	0.9 – 1.4	Precipitation hardening
Cobalt	12 – 15	Solid solution strengthening
Tantalum	3.8 – 4.8	Carbide former
Carbon	0.05 – 0.15	Carbide former
Boron	0.006 – 0.012	Grain boundary strengthener

Trace quantities of zirconium, magnesium and sulphur are also added for enhanced properties. Properties of IN939 Powder IN939 possesses an exceptional combination of properties:

Property	Description
High strength	Excellent tensile and creep rupture strength up to 1050°C
Thermal stability	Strength maintained up to 1000°C
Creep resistance	High stress-rupture life at high temperatures
Oxidation resistance	Forms protective Cr2O3 oxide scale
Thermal fatigue resistance	Resists cracking during thermal cycling
Phase stability	Microstructure stable after prolonged exposures
Corrosion resistance	Resistant to hot corrosion, oxidation, sulfidation

The properties enable use under extreme thermal and mechanical loads. 3D Printing Parameters for IN939 Powder Typical AM processing parameters for IN939 include:

Parameter	Typical value	Purpose
Layer thickness	20-50 μm	Resolution vs build speed
Laser power	250-500 W	Sufficient melting without evaporation
Scan speed	800-1200 mm/s	Density vs production rate
Hatch spacing	100-200 μm	Mechanical properties
Support structure	Minimal	Easy removal
Hot isostatic pressing	1160°C, 100 MPa, 3h	Eliminate porosity

Parameters are optimized for attributes like density, microstructure, build rate, and post-processing requirements. Applications of 3D Printed IN939 Parts Additively manufactured IN939 components serve critical applications including:

Industry	Components
Aerospace	Turbine blades, vanes, combustors
Power generation	Hot gas path parts, heat exchangers
Automotive	Turbocharger wheels, valves
Chemical processing	Pumps, valves, reaction vessels

Benefits over conventionally processed IN939 include complex geometries and reduced lead time. Specifications of IN939 Powder for 3D Printing IN939 powder for AM must meet exacting specifications:

Parameter	Specification
Particle size	15-45 μm typical
Particle shape	Spherical morphology
Apparent density	> 4 g/cc
Tap density	> 6 g/cc
Hall flow rate	> 23 sec for 50 g
Purity	>99.9%
Oxygen content	<100 ppm

Tighter tolerances, custom size distributions, and controlled impurity levels available. Handling and Storage of IN939 Powder As a reactive powder, careful handling of IN939 is needed: Store sealed containers in a cool, inert atmosphere Prevent contact with moisture, oxygen, acids Use properly grounded equipment Avoid dust accumulation to minimize explosion risk Local exhaust ventilation recommended Wear appropriate PPE while handling Proper techniques and controls prevent IN939 powder oxidation or contamination. Inspection and Testing of IN939 Powder

Method	Parameters Tested
Sieve analysis	Particle size distribution
SEM imaging	Particle morphology
EDX	Chemistry and composition
XRD	Phases present
Pycnometry	Density
Hall flow rate	Powder flowability

Testing per applicable ASTM standards ensures batch consistency. Comparing IN939 to Alternative Alloy Powders IN939 compares to other Ni-based superalloys as:

Alloy	High Temperature Strength	Cost	Printability	Ductility
IN939	Excellent	High	Excellent	Low
IN738	Good	Medium	Excellent	Medium
IN718	Fair	Low	Good	Excellent
Hastelloy X	Excellent	High	Fair	Medium

For balanced properties and processability, IN939 supersedes alternatives like IN718 Powder or Hastelloy X Powder. Pros and Cons of IN939 Powder for 3D Printing

Pros	Cons
Exceptional high temperature strength	Expensive compared to IN718
Excellent oxidation and creep resistance	Significant parameter optimization needed
Complex geometries feasible	Limited room temperature ductility
Faster processing than cast/wrought	Controlled storage and handling environment
Comparable properties to cast alloy	Difficult to machine after printing

IN939 enables high-performance printed parts but with higher costs and controlled processing needs. Frequently Asked Questions about IN939 Powder for 3D Printing Q: What particle size range works best for printing IN939? A: A particle size range of 15-45 microns provides good flowability combined with high resolution and density. Finer particles below 10 microns can improve density and surface finish. Q: Does IN939 require any post-processing after 3D printing? A: Post processes like hot isostatic pressing, heat treatment, and machining are usually needed to eliminate porosity, relieve stresses, and achieve final tolerances and surface finish. Q: What precision can be achieved with IN939 printed parts? A: After post-processing, dimensional accuracy and surface finish comparable to CNC machined parts can be achieved with IN939 AM components. Q: Are support structures necessary for printing IN939 powder? A: Minimal supports are recommended for complex channels and overhangs to prevent deformation and facilitate easy removal. IN939 powder has good flowability. Q: What alloy powder is the closest alternative to IN939 for AM? A: IN738 is the closest alternative in terms of balanced properties and maturity for additive manufacturing. Other alloys like IN718 or Hastelloy X have some trade-offs. Q: Is IN939 compatible with direct metal laser sintering (DMLS)? A: Yes, IN939 is readily processable by major powder bed fusion techniques including DMLS along with selective laser melting (SLM) and electron beam melting (EBM). Q: What density is achievable with 3D printed IN939 components? A: With optimized parameters, densities over 99% are achievable, matching properties of traditionally processed IN939 products. Q: How do the properties of printed IN939 compare to cast alloy? A: Additively manufactured IN939 exhibits comparable or better mechanical properties and microstructure compared to conventional cast and wrought forms. Q: What defects can occur when printing with IN939 powder? A: Potential defects are cracking, distortion, porosity, surface roughness, incomplete fusion etc. Most can be prevented by proper parameter optimization and powder quality. Q: Is hot isostatic pressing (HIP) mandatory for IN939 AM parts? A: HIP eliminates internal voids and improves fatigue resistance. For less demanding applications, heat treatment alone may suffice instead of HIP.

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IN939 Powder

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IN939 Powder

Product	IN939 Powder
CAS No.	N/A
Appearance	Gray Powder
Purity	≥99%, ≥99.9%, ≥95%(Other purities are also available)
APS	1-5 µM, 10-53 µM (Can be customized), Ask for other available size range.
Ingredient	C6H6N6O6
Density	8.15g/cm3
Molecular Weight	N/A
Product Codes	NCZ-DCY-280/25

IN939 Description:

IN939 Powder Related Information :

Storage Conditions: Airtight sealed, avoid light and keep dry at room temperature. Please contact us for customization and price inquiry Email: contact@nanochemazone.com Note: We supply different size ranges of Nano and micron as per the client’s requirements and also accept customization in various parameters. Best IN939 Powder for 3D Printing in 2024 IN939 powder is a nickel-based superalloy that exhibits exceptional mechanical properties and high resistance to corrosion and oxidation. It is primarily composed of nickel, chromium, cobalt, molybdenum, and tantalum. This composition gives IN939 powder its remarkable strength, heat resistance, and stability at elevated temperatures. Overview of IN939 Powder for 3D Printing IN939 is a high-performance nickel-based superalloy powder designed for additive manufacturing of critical components needing exceptional mechanical properties at high temperatures. This article provides a comprehensive guide to IN939 powder for 3D printing applications across aerospace, automotive, energy and industrial sectors. Key aspects covered include IN939 composition, properties, print parameters, applications, specifications, suppliers, handling, inspection, comparisons to alternatives, advantages and limitations, and frequently asked questions. Quantitative data is presented in easy-to-reference tables. Composition of IN939 Powder IN939 has a complex precipitation hardening alloy composition:

Element	Weight %	Purpose
Nickel	Balance	Principal matrix element
Chromium	15 – 18	Oxidation resistance
Aluminum	3.8 – 4.8	Precipitation hardening
Titanium	0.9 – 1.4	Precipitation hardening
Cobalt	12 – 15	Solid solution strengthening
Tantalum	3.8 – 4.8	Carbide former
Carbon	0.05 – 0.15	Carbide former
Boron	0.006 – 0.012	Grain boundary strengthener

Trace quantities of zirconium, magnesium and sulphur are also added for enhanced properties. Properties of IN939 Powder IN939 possesses an exceptional combination of properties:

Property	Description
High strength	Excellent tensile and creep rupture strength up to 1050°C
Thermal stability	Strength maintained up to 1000°C
Creep resistance	High stress-rupture life at high temperatures
Oxidation resistance	Forms protective Cr2O3 oxide scale
Thermal fatigue resistance	Resists cracking during thermal cycling
Phase stability	Microstructure stable after prolonged exposures
Corrosion resistance	Resistant to hot corrosion, oxidation, sulfidation

The properties enable use under extreme thermal and mechanical loads. 3D Printing Parameters for IN939 Powder Typical AM processing parameters for IN939 include:

Parameter	Typical value	Purpose
Layer thickness	20-50 μm	Resolution vs build speed
Laser power	250-500 W	Sufficient melting without evaporation
Scan speed	800-1200 mm/s	Density vs production rate
Hatch spacing	100-200 μm	Mechanical properties
Support structure	Minimal	Easy removal
Hot isostatic pressing	1160°C, 100 MPa, 3h	Eliminate porosity

Industry	Components
Aerospace	Turbine blades, vanes, combustors
Power generation	Hot gas path parts, heat exchangers
Automotive	Turbocharger wheels, valves
Chemical processing	Pumps, valves, reaction vessels

Benefits over conventionally processed IN939 include complex geometries and reduced lead time. Specifications of IN939 Powder for 3D Printing IN939 powder for AM must meet exacting specifications:

Parameter	Specification
Particle size	15-45 μm typical
Particle shape	Spherical morphology
Apparent density	> 4 g/cc
Tap density	> 6 g/cc
Hall flow rate	> 23 sec for 50 g
Purity	>99.9%
Oxygen content	<100 ppm

Method	Parameters Tested
Sieve analysis	Particle size distribution
SEM imaging	Particle morphology
EDX	Chemistry and composition
XRD	Phases present
Pycnometry	Density
Hall flow rate	Powder flowability

Testing per applicable ASTM standards ensures batch consistency. Comparing IN939 to Alternative Alloy Powders IN939 compares to other Ni-based superalloys as:

Alloy	High Temperature Strength	Cost	Printability	Ductility
IN939	Excellent	High	Excellent	Low
IN738	Good	Medium	Excellent	Medium
IN718	Fair	Low	Good	Excellent
Hastelloy X	Excellent	High	Fair	Medium

For balanced properties and processability, IN939 supersedes alternatives like IN718 Powder or Hastelloy X Powder. Pros and Cons of IN939 Powder for 3D Printing

Pros	Cons
Exceptional high temperature strength	Expensive compared to IN718
Excellent oxidation and creep resistance	Significant parameter optimization needed
Complex geometries feasible	Limited room temperature ductility
Faster processing than cast/wrought	Controlled storage and handling environment
Comparable properties to cast alloy	Difficult to machine after printing

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INCONEL 625 Nickel Alloy Nanopowder

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MF:	Ni:Cr
Chemical Name:	INCONEL 625 Nickel Alloy Nanopowder
Purity:	> 99.99%
APS:	80-100 nm (Size Customization possible)
Form:	Nanopowder
Product Number:	NCZA115
CAS Number:	7440-02-0 / 7440-47-3

Size Options: also available in the micro size range and 325 Mesh, 200 Mesh, etc. (Ask for the customization)

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Inconel 625 Powder

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Inconel 625 Powder

Product	Inconel 625 Powder
CAS No.	7440-02-0
Appearance	Gray or Metallic Powder
Purity	≥99%, ≥99.9%, ≥95%(Other purities are also available)
APS	1-5 µM, 10-53 µM (Can be customized), Ask for other available size range.
Ingredient	NiCr22Mo9Nb
Density	8.44g/cm3
Molecular Weight	N/A
Product Codes	NCZ-DCY-234/25

Inconel 625 Description:

Inconel 625 Powder is one of the numerous advanced ceramic materials manufactured by Nanochemazone. Nanochemazone produces too many standard grades when applicable, including Mil Spec (military grade); ACS, Reagent and Technical Grade; Food, Agricultural and Pharmaceutical Grade; Optical Grade, USP and EP/BP (European Pharmacopoeia/British Pharmacopoeia) and follows applicable ASTM testing standards. Typical and custom packaging is available. Additional technical, research and safety (MSDS) information are available. Please request a quote above for more information on lead time and pricing

Inconel 625 Powder Related Information :

Metal Powder	Size	Quantity	Price/kg	Size	Quantity	Price/kg
Inconel 625	0-20μm	1KG	$59	20-63μm	1KG	$98.30
		10KG	$39		10KG	$69.10
		100KG	$34		100KG	$64.50

GH3625 powder Inconel 625 powder is an alloy powder used for metal additive manufacturing processes like selective laser sintering (SLS) and direct metal laser sintering (DMLS). It is a nickel-based superalloy that offers high strength, corrosion resistance, and excellent high-temperature properties. GH3625 is designed specifically for additive manufacturing to produce complex, dense parts with exceptional mechanical properties comparable to wrought materials. It enables the production of lightweight components with complex geometries for aerospace, automotive, medical, and industrial applications. This guide provides a detailed overview of GH3625 powder covering its composition, properties, applications, specifications, pricing, advantages, and limitations. Comparisons are made to other common alloys like Inconel 718 and Stellite 21 to highlight the performance and suitability of GH3625 for different uses. An FAQ section addresses key questions about tGH3625 powder Inconel 625 powder Composition GH3625 has a complex chemical composition designed to provide a combination of high strength, resistance to thermal fatigue, oxidation, and corrosion resistance. Here is an overview of its composition:

Element	Weight %
Nickel	Balance
Chromium	15-17%
Cobalt	10%
Molybdenum	8-10%
Tantalum	5-6%
Aluminum	1.2-1.7%
Titanium	0.5-1.2%
Boron	0.01%

Nickel forms the base of this superalloy providing ductility and toughness. Elements like chromium, cobalt, and molybdenum contribute to high temperature strength through solid solution strengthening. Tantalum provides solid solution strengthening and forms carbide particles for precipitation hardening. Aluminum and titanium form the gamma prime phase Ni3(Al,Ti) to give excellent high temperature mechanical properties. Boron enhances grain boundary strength. The balanced composition gives GH3625 powder excellent weldability compared to precipitation hardening stainless steels. It can be easily post-processed through hot isostatic pressing (HIP), heat treatment, and machining. GH3625 powder Inconel 625 powder Properties GH3625 powder has the following physical and mechanical properties that make it suitable for demanding applications: GH3625 powder Inconel 625 powder Properties

Property	Value
Density	8.1-8.5 g/cc
Melting Point	1260-1335°C
Thermal Conductivity	11-12.5 W/mK
Coefficient of Thermal Expansion	12.5-13.5 x 10<sup>-6</sup>/K
Modulus of Elasticity	156-186 GPa
Poission’s Ratio	0.29-0.33
Tensile Strength	1050-1280 MPa
Yield Strength (0.2% offset)	860-1050 MPa
Elongation	8-15%
Hardness	32-38 HRC

The high melting point, thermal conductivity, and low coefficient of thermal expansion enable good dimensional stability under high temperature service environments up to 1000°C for limited periods. The alloy has excellent tensile and yield strength comparable to wrought materials along with good ductility and fracture toughness. It exhibits high hardness, resistance to wear, galling, and abrasion. The properties allow GH3625 to outperform stainless steels, cobalt alloys, and even rival precipitation hardening nickel superalloys in high temperature strength. It also offers better weldability than Inconel 718. GH3625 powder Inconel 625 powder Applications

Industry	Components
Aerospace	Turbine blades, combustor parts, nozzle guide vanes
Automotive	Turbocharger wheels, manifolds, valves
Oil and Gas	Wellhead parts, downhole tools, valves
Power Generation	Heat exchangers, burner components
Chemical Processing	Pump impellers, valves, reaction vessels
Medical	Dental implants, prosthetics, surgical instruments

The ability to 3D print complex geometries allows consolidating multiple parts into single components and lightweight lattice structures. This enables faster printing of single-piece components versus assembling multiple sections. GH3625 is used to print blades, impellers, plates, discs, tubes with conformal cooling channels, and other mission-critical components working under high pressures and temperatures. GH3625 powder Inconel 625 powder Specifications GH3625 powder for AM processes is available in different size distributions, shapes, and formulations from various powder manufacturers. GH3625 Powder Types

Specification	Details
Particle Size Distribution	15-45 μm, 15-53 μm, 53-150 μm
Particle Shape	Spherical, satellite, polyhedral
Alloy Modifications	With B, C, Zr, Nb, Ta
Manufacturing Method	Gas atomization, plasma atomization

Gas atomization and plasma atomization produce spherical powders optimal for SLS/DMLS processes. Satellite powders have higher tap density and improve powder flowability. Smaller 15-45 μm powders provide high resolution and surface finish while larger 53-150 μm allow faster build speeds. Different alloying additions like boron, carbon, zirconium, niobium, and tantalum are used to tailor material properties. GH3625 powder Inconel 625 powder Standards

Standard	Description
ASTM F3056	Standard specification for additive manufacturing nickel alloy
AMS7016	Nickel alloy powder for high temperature service
ASME B46.1	Surface texture requirements

GH3625 powder is qualified based on composition limits, particle size distribution, morphology, flowability, apparent density, and microstructure per ASTM F3056. Additional testing as per application standards is requireGH3625 powder Inconel 625 powder Pros and Cons GH3625 has the following advantages that make it a popular choice: GH3625 Pros Excellent strength and hardness up to 1000°C Good corrosion and oxidation resistance Weldable for post-processing Higher ductility than Inconel 718 Can be age hardened by heat treatment Complex geometries enabled by AM Faster and cheaper than castings Reduces part count through consolidation GH3625 Cons More expensive than stainless steels Lower strength than Inconel 718 above 550°C Susceptible to strain-age cracking Requires hot isostatic pressing (HIP) Difficult to machine – requires specialist tools Limited supplier data on long term performance Proper selection of AM process parameters and post-processing mitigates some of the limitations of GH3625 powder. Comparison of GH3625 powder Inconel 625 powder with Inconel 718 and Stellite 21 GH3625 occupies a niche between Inconel 718 and Stellite 21 in terms of properties and cost: Alloy Comparison

Property	GH3625	Inconel 718	Stellite 21
Cost	Medium	High	Low
Density	High	Medium	High
Strength	Medium	Very High	Medium
Hardness	High	Medium	Very High
Wear Resistance	Medium	Low	Very High
Corrosion Resistance	Medium	High	Medium
Oxidation Resistance	Medium	High	Medium
Thermal Stability	Up to 1000°C	Up to 700°C	Up to 900°C
Weldability	Good	Poor	Medium
Manufacturability	Medium	Difficult	Easy

GH3625 matches or exceeds the performance of Stellite 21 cobalt alloys in wear and corrosion resistance but at lower cost. It approaches the strength of Inconel 718 up to 550°C and offers better weldability and manufacturability. This makes it a cost-effective alternative for many applications requiring performance between these standard alloys. The ability to 3D print complex geometries also gives it an edge. GH3625 powder Inconel 625 powder – FAQs Q: What is GH3625 powder? A: GH3625 is a nickel-based superalloy powder specifically designed for additive manufacturing processes like selective laser sintering (SLS) and direct metal laser sintering (DMLS). It provides an excellent combination of high temperature strength, hardness, wear and corrosion resistance. Q: What is GH3625 powder used for? A: GH3625 powder is used to 3D print critical components like turbine blades, manifolds, impellers, heat exchangers that require high mechanical properties, dimensional stability, and thermal resistance up to 1000°C. It finds applications across aerospace, automotive, energy, chemical processing, and medical industries. Q: What metal 3D printing processes use GH3625 powder? A: Selective laser sintering (SLS) and direct metal laser sintering (DMLS) are powder bed fusion 3D printing processes commonly used with GH3625 powder. Binder jetting is also suitable for GH3625. Q: What are the material properties of GH3625? A: GH3625 has excellent tensile strength 1050-1280 MPa, yield strength 860-1050 MPa, and hardness 32-38 HRC similar to wrought materials. It has good ductility of 8-15% elongation and high resistance to wear, galling, abrasion, and corrosion. Thermal properties allow use up to 1000°C. Q: Does GH3625 powder require heat treatment? A: Yes, GH3625 parts printed using SLS/DMLS require hot isostatic pressing (HIP) followed by heat treatment to achieve optimal mechanical properties, material consolidation, and microstructure. HIP helps close internal pores and voids. Q: Is GH3625 weldable? A: GH3625 is designed to have excellent weldability compared to precipitation hardening stainless steels and Inconel 718. This allows repairing and joining AM GH3625 parts through welding. Stress relieving may be required after welding to prevent cracking. Q: Is GH3625 machinable? A: GH3625 is difficult to machine compared to stainless steel and requires high-speed machining with specialist carbide tools. Tool wear is higher so optimal feeds, speeds, and tool paths are necessary. Q: How much does GH3625 powder cost? A: GH3625 typically costs between $90-250 per kg based on order size, particle size distribution, manufacturing method, and additional testing/qualification requirements. It is more expensive than stainless steel powders but lower cost than Inconel 718.

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Inconel 625 Powder

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Inconel 625 Powder

Product	Inconel 625 Powder
CAS No.	7440-02-0
Appearance	Gray Powder
Purity	≥99%, ≥99.9%, ≥95%(Other purities are also available)
APS	1-5 µM, 10-53 µM (Can be customized), Ask for other available size range.
Ingredient	NiCr22Mo9Nb
Density	8.4g/cm3
Molecular Weight	N/A
Product Codes	NCZ-DCY-292/25

Inconel 625 Description:

Inconel 625 Powder Related Information :

Metal Powder	Size	Quantity	Price/kg	Size	Quantity	Price/kg
Inconel 625	0-20μm	1KG	$59	20-63μm	1KG	$98.30
		10KG	$39		10KG	$69.10
		100KG	$34		100KG	$64.50

Overview GH3625 powder Inconel 625 powder is an alloy powder used for metal additive manufacturing processes like selective laser sintering (SLS) and direct metal laser sintering (DMLS). It is a nickel-based superalloy that offers high strength, corrosion resistance, and excellent high-temperature properties. GH3625 is designed specifically for additive manufacturing to produce complex, dense parts with exceptional mechanical properties comparable to wrought materials. It enables the production of lightweight components with complex geometries for aerospace, automotive, medical, and industrial applications. This guide provides a detailed overview of GH3625 powder covering its composition, properties, applications, specifications, pricing, advantages, and limitations. Comparisons are made to other common alloys like Inconel 718 and Stellite 21 to highlight the performance and suitability of GH3625 for different uses. An FAQ section addresses key questions about this material. GH3625 powder Inconel 625 powder Composition GH3625 has a complex chemical composition designed to provide a combination of high strength, resistance to thermal fatigue, oxidation, and corrosion resistance. Here is an overview of its composition:

Element	Weight %
Nickel	Balance
Chromium	15-17%
Cobalt	10%
Molybdenum	8-10%
Tantalum	5-6%
Aluminum	1.2-1.7%
Titanium	0.5-1.2%
Boron	0.01%

Property	Value
Density	8.1-8.5 g/cc
Melting Point	1260-1335°C
Thermal Conductivity	11-12.5 W/mK
Coefficient of Thermal Expansion	12.5-13.5 x 10<sup>-6</sup>/K
Modulus of Elasticity	156-186 GPa
Poission’s Ratio	0.29-0.33
Tensile Strength	1050-1280 MPa
Yield Strength (0.2% offset)	860-1050 MPa
Elongation	8-15%
Hardness	32-38 HRC

Industry	Components
Aerospace	Turbine blades, combustor parts, nozzle guide vanes
Automotive	Turbocharger wheels, manifolds, valves
Oil and Gas	Wellhead parts, downhole tools, valves
Power Generation	Heat exchangers, burner components
Chemical Processing	Pump impellers, valves, reaction vessels
Medical	Dental implants, prosthetics, surgical instruments

Specification	Details
Particle Size Distribution	15-45 μm, 15-53 μm, 53-150 μm
Particle Shape	Spherical, satellite, polyhedral
Alloy Modifications	With B, C, Zr, Nb, Ta
Manufacturing Method	Gas atomization, plasma atomization

Standard	Description
ASTM F3056	Standard specification for additive manufacturing nickel alloy
AMS7016	Nickel alloy powder for high temperature service
ASME B46.1	Surface texture requirements

GH3625 powder is qualified based on composition limits, particle size distribution, morphology, flowability, apparent density, and microstructure per ASTM F3056. Additional testing as per application standards is required. GH3625 powder Inconel 625 powder Pros and Cons GH3625 has the following advantages that make it a popular choice: GH3625 Pros Excellent strength and hardness up to 1000°C Good corrosion and oxidation resistance Weldable for post-processing Higher ductility than Inconel 718 Can be age hardened by heat treatment Complex geometries enabled by AM Faster and cheaper than castings Reduces part count through consolidation GH3625 Cons More expensive than stainless steels Lower strength than Inconel 718 above 550°C Susceptible to strain-age cracking Requires hot isostatic pressing (HIP) Difficult to machine – requires specialist tools Limited supplier data on long term performance Proper selection of AM process parameters and post-processing mitigates some of the limitations of GH3625 powder. Comparison of GH3625 powder Inconel 625 powder with Inconel 718 and Satellite 21 GH3625 occupies a niche between Inconel 718 and Satellite 21 in terms of properties and cost: Alloy Comparison

Property	GH3625	Inconel 718	Satellite 21
Cost	Medium	High	Low
Density	High	Medium	High
Strength	Medium	Very High	Medium
Hardness	High	Medium	Very High
Wear Resistance	Medium	Low	Very High
Corrosion Resistance	Medium	High	Medium
Oxidation Resistance	Medium	High	Medium
Thermal Stability	Up to 1000°C	Up to 700°C	Up to 900°C
Weldability	Good	Poor	Medium
Manufacturability	Medium	Difficult	Easy

GH3625 matches or exceeds the performance of Satellite 21 cobalt alloys in wear and corrosion resistance but at lower cost. It approaches the strength of Inconel 718 up to 550°C and offers better weldability and manufacturability. This makes it a cost-effective alternative for many applications requiring performance between these standard alloys. The ability to 3D print complex geometries also gives it an edge. GH3625 powder Inconel 625 powder – FAQs Q: What is GH3625 powder? A: GH3625 is a nickel-based superalloy powder specifically designed for additive manufacturing processes like selective laser sintering (SLS) and direct metal laser sintering (DMLS). It provides an excellent combination of high temperature strength, hardness, wear and corrosion resistance. Q: What is GH3625 powder used for? A: GH3625 powder is used to 3D print critical components like turbine blades, manifolds, impellers, heat exchangers that require high mechanical properties, dimensional stability, and thermal resistance up to 1000°C. It finds applications across aerospace, automotive, energy, chemical processing, and medical industries. Q: What metal 3D printing processes use GH3625 powder? A: Selective laser sintering (SLS) and direct metal laser sintering (DMLS) are powder bed fusion 3D printing processes commonly used with GH3625 powder. Binder jetting is also suitable for GH3625. Q: What are the material properties of GH3625? A: GH3625 has excellent tensile strength 1050-1280 MPa, yield strength 860-1050 MPa, and hardness 32-38 HRC similar to wrought materials. It has good ductility of 8-15% elongation and high resistance to wear, galling, abrasion, and corrosion. Thermal properties allow use up to 1000°C. Q: Does GH3625 powder require heat treatment? A: Yes, GH3625 parts printed using SLS/DMLS require hot isostatic pressing (HIP) followed by heat treatment to achieve optimal mechanical properties, material consolidation, and microstructure. HIP helps close internal pores and voids. Q: Is GH3625 weldable? A: GH3625 is designed to have excellent weldability compared to precipitation hardening stainless steels and Inconel 718. This allows repairing and joining AM GH3625 parts through welding. Stress relieving may be required after welding to prevent cracking. Q: Is GH3625 machinable? A: GH3625 is difficult to machine compared to stainless steel and requires high-speed machining with specialist carbide tools. Tool wear is higher so optimal feeds, speeds, and tool paths are necessary. Q: How much does GH3625 powder cost? A: GH3625 typically costs between $90-250 per kg based on order size, particle size distribution, manufacturing method, and additional testing/qualification requirements. It is more expensive than stainless steel powders but lower cost than Inconel 718.

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