Fuel Cell Catalysts Suppliers USA
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Product | Description | |
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Dealloyed Pt-Co core-shell fuel cell catalyst on carbon Quick inquiry Where to buy Suppliers range | Dealloyed Pt-Co core-shell fuel cell catalyst on carbon. Molecular formula: CoPt. | |
Dealloyed Pt-Cu core-shell fuel cell catalyst on carbon Quick inquiry Where to buy Suppliers range | Dealloyed Pt-Cu core-shell fuel cell catalyst on carbon. Molecular formula: CuPt. | |
Bis(4-fluorophenyl)phenylphosphine oxide Quick inquiry Where to buy Suppliers range | Catalyst for hydroformylation reactions Used for preparation of chlorine-tolerant polymers for desalination Crosslinking agent in preparation of polymer electrolyte membranes for fuel cell applications. Synonyms: Bis(4-fluorophenyl)phenylphosphineoxide. Grades: 97%. CAS No. 54300-32-2. Molecular formula: C18H13F2OP. Mole weight: 314.27. | |
Bis(4-fluorophenyl)phenylphosphine oxide Quick inquiry Where to buy Suppliers range | Bis(4-fluorophenyl)phenylphosphine oxide. Uses: Bis(4-fluorophenyl)phenylphosphine oxide is a catalyst for hydroformylation reactions,it is also used for preparation of chlorine-tolerant polymers for desalination Crosslinking agent in preparation of polymer electrolyte membranes for fuel cell applications. Group: Heterocyclic Organic Compound. Alternative Names: bis(p-fluorophenyl)phenylphosphine oxide. CAS No. 54300-32-2. Product ID: ACM54300322-1. Molecular formula: (FC6H4)2P(O)C6H5. Mole weight: 314.27. IUPAC Name: 1-fluoro-4-[(4-fluorophenyl)-phenylphosphoryl]benzene. Boiling Point: 454.5° C at 760 mmHg (Predicted). Melting Point: 125-131° C. Density: 1.3 g/cm3(Predicted). | |
Cerium Oxide Dispersion (CeO2, Purity, 99.99%, Diameter: 30-50nm) Quick inquiry Where to buy Suppliers range | Nano ceria particles have been widely used in ultraviolet absorbers, polishing powders, fluorescent materials, catalysts and fuel cells due to their unique physical and chemical properties, and these properties are related to structure, morphology and particle size. closely related. There are many preparation methods for nano-ceria, such as: hydrothermal method, precipitation method, sol-gel method, microemulsion method and so on. At low temperature (T < 450°C), CeO2 can form a series of oxides with different compositions. It is worth noting that even if a considerable amount of oxygen is lost from the crystal lattice, CeO2-x can still maintain a fluorite-type crystal structure after forming a large number of oxygen vacancies, and this metastable oxide is easily oxidized when exposed to an oxidizing environment. CeO2 has excellent storage and release oxygen function and redox reaction ability. Uses: ·Efficient catalyst ·Precision polishing ·Chemical additives ·Electronic Ceramics, Structural Ceramics ·Battery material. Group: Metal Oxide Colloids. CAS No. 1306-38-3. Molecular Weight: 172.11 g/mol. Boiling Point: 2600 °C. Flash Point: 99.9 %. Purity: 7.13 g/mL at 25°C (lit.). | |
Cerium Oxide Nanoparticle Dispersion (CeO2, Purity: 99.99%, Diameter: 30nm) Quick inquiry Where to buy Suppliers range | Nano ceria particles have been widely used in ultraviolet absorbers, polishing powders, fluorescent materials, catalysts and fuel cells due to their unique physical and chemical properties, and these properties are related to structure, morphology and particle size. closely related. There are many preparation methods for nano-ceria, such as: hydrothermal method, precipitation method, sol-gel method, microemulsion method and so on. At low temperature (T < 450°C), CeO2 can form a series of oxides with different compositions. It is worth noting that even if a considerable amount of oxygen is lost from the crystal lattice, CeO2-x can still maintain a fluorite-type crystal structure after forming a large number of oxygen vacancies, and this metastable oxide is easily oxidized when exposed to an oxidizing environment. CeO2 has excellent storage and release oxygen function and redox reaction ability. Uses: ·Efficient catalyst ·Precision polishing ·Chemical additives ·Electronic Ceramics, Structural Ceramics ·Battery material. Group: Metal Oxide Colloids. CAS No. 1306-38-3. Molecular Weight: 172.11 g/mol. Boiling Point: 2600 °C. Flash Point: 99.9 %. Purity: 7.13 g/mL at 25°C (lit.). | |
Electrospun Carbon Nanofiber Membrane Quick inquiry Where to buy Suppliers range | This product uses electrospun polyacrylonitrile fiber as precursor, and prepares electrospun carbon nanofiber membrane by pre-oxidation, carbonization and graphitization. The cross-sectional area is reduced by more than 400 times, which brings a series of superior performance and has a wide range of application values. Uses: Application fields include high-strength composite materials, conductive composite materials, electromagnetic shielding, electrochemical electrodes, catalyst carriers, separation filtration, heating elements, fuel cell gas diffusion layers, etc. Group: Electrospun Carbon Nanofiber Series. Flash Point: 99.9999% (6N). | |
Gold nanoparticles, 2% on carbon black (surfactant and reactant-free) Quick inquiry Where to buy Suppliers range | Gold-coloured powder or tiny sheets;Soft yellow metal; gold-colored powder or tiny sheets. Group: Fuel Cells; Nano Catalysts. CAS No. 7440-57-5. IUPAC Name: gold. Molecular Weight: 196.96657g/mol. Molecular Formula: Au;Au. SMILES: [Au]. | |
Guanidinium Bromide, anhydrous Quick inquiry Where to buy Suppliers range | ≥99%, anhydrous. Uses: Organohalide based perovskites have emerged as an important class of material for solar cell applications. Our perovskites precursors with extremely low water contents are useful for synthesizing mixed cation or anion perovskites needed for the optimization of the band gap, carrier diffusion length and power conversion efficiency of perovskites based solar cells.guanidinium Bromide (gBr) can be used in the functionalization of poly(2,6-dimethyl-1,4-phenylene oxide) (PPO) for the formation of the anion exchange membrane for fuel cells applications. It can also be used in the preparation of an amphiphilic catalyst for the production of biodiesel. Group: Bromide. CAS No. 19244-98-5. Molecular Weight: 139.98 g/mol. | |
Nitric acid palladium salt hydrate Quick inquiry Where to buy Suppliers range | Nitric acid palladium salt hydrate. Uses: Palladium(II) nitrate hydrate is the catalyst for alkene nitration to glycol dinitrates; also used as a precursor to supported Pd catalysts. Palladium(II) nitrate hydrate is also the reactant for: ? Preparation of platinum-palladium/carbon alloy nanocatalysts for methanol-tolerant oxygen reduction reaction in fuel cells ? Synthesis. Group: Palladium series catalysts. Alternative Names: TRA0059391; 207596-32-5; Palladium(2+) nitrate hydrate (1:2:1); PALLADIUM (II) NITRATE,HYDRATE; Palladous nitrate hydrate; RT-001123; DTZRLFJKQHIVQA-UHFFFAOYSA-N; CTK3J2908; Palladium nitrate hydrate; 82279-70-7. CAS No. 207596-32-5. Molecular formula: H2N2O7Pd. Mole weight: 248.443g/mol. IUPAC Name: palladium(2+);dinitrate;hydrate. Exact Mass: 247.89g/mol. SMILES: [N+](=O)([O-])[O-].[N+](=O)([O-])[O-].O.[Pd+2]. InChI: InChI=1S/2NO3.H2O.Pd/c2*2-1(3)4;;/h;;1H2;/q2*-1;;+2. InChIKey: DTZRLFJKQHIVQA-UHFFFAOYSA-N. H-Bond Donor: 1. H-Bond Acceptor: 7. Monoisotopic Mass: 247.89g/mol. | |
Palladium Quick inquiry Where to buy Suppliers range | Palladium and its alloys are used for hydrogen purification in fuel cells. Energy dispersive x-ray diffraction during electrochemical loading of palladium foils with hydrogen and deuterium was studied. Palladium foil was tested as a catalyst for Suzuki-Miyaura cross coupling reaction. Uses: Among the platinum group metals, palladium is the least noble metal, exhibiting greater reactivity than other metals of the group. The metal forms mostly bivalent compounds, although a small number of tetravalent and a fewer trivalent compounds are known. Palladium exhibits a strong tendency to form complexes, most of which are four-coordinated square planar complexes of the metal in +2 oxidation state. When heated in air or oxygen above 350°C, palladium forms a black oxide, PdO coated over its surface. On further heating to over 790°C, the oxide decomposes back to the metal. Palladium dissolves more oxygen in molten state than in solid form. Palladium reacts with fluorine and chlorine at 500°C forming its halides, the black PdF3 and the red deliquescent solid PdCl2. Palladium is attacked by concentrated nitric acid, particularly in the presence of nitrogen oxides. The reaction is slow in dilute nitric acid. Finely divided palladium metal reacts with warm nitric acid forming palladium(II) nitrate, Pd(NO3)2. Hydrochloric acid has no affect on the metal. Reaction with boiling sulfuric acid yields palladium sulfate, PdSO4, and sulfur dioxide. Palladium readily dissolves in aqua regia forming chloropalladic acid, H2PdCl6. Evaporation of this solution yields palladium(II) chloride, PdCl2. Palladium absorbs hydrogen over 800 times its own volume over a range of temperature. By doing so, the metal swells, becoming brittle and cracked. Such absorption of hydrogen decreases the electrical conductivity of the metal. Also, such absorption activates molecular hydrogen, dissociating it to atomic hydrogen. Group: Oil & Gas. Alternative Names: Palladium (powder),Palladium black,Palladium element. CAS No. 7440-5-3. IUPAC Name: palladium. Molecular Weight: 106.42. Molecular Formula: Pd. SMILES: [Pd]. | |
Palladium Quick inquiry Where to buy Suppliers range | Palladium and its alloys are used for hydrogen purification in fuel cells. Energy dispersive x-ray diffraction during electrochemical loading of palladium foils with hydrogen and deuterium was studied. Palladium foil was tested as a catalyst for Suzuki-Miyaura cross coupling reaction. Uses: Among the platinum group metals, palladium is the least noble metal, exhibiting greater reactivity than other metals of the group. The metal forms mostly bivalent compounds, although a small number of tetravalent and a fewer trivalent compounds are known. Palladium exhibits a strong tendency to form complexes, most of which are four-coordinated square planar complexes of the metal in +2 oxidation state. When heated in air or oxygen above 350°C, palladium forms a black oxide, PdO coated over its surface. On further heating to over 790°C, the oxide decomposes back to the metal. Palladium dissolves more oxygen in molten state than in solid form. Palladium reacts with fluorine and chlorine at 500°C forming its halides, the black PdF3 and the red deliquescent solid PdCl2. Palladium is attacked by concentrated nitric acid, particularly in the presence of nitrogen oxides. The reaction is slow in dilute nitric acid. Finely divided palladium metal reacts with warm nitric acid forming palladium(II) nitrate, Pd(NO3)2. Hydrochloric acid has no affect on the metal. Reaction with boiling sulfuric acid yields palladium sulfate, PdSO4, and sulfur dioxide. Palladium readily dissolves in aqua regia forming chloropalladic acid, H2PdCl6. Evaporation of this solution yields palladium(II) chloride, PdCl2. Palladium absorbs hydrogen over 800 times its own volume over a range of temperature. By doing so, the metal swells, becoming brittle and cracked. Such absorption of hydrogen decreases the electrical conductivity of the metal. Also, such absorption activates molecular hydrogen, dissociating it to atomic hydrogen. Group: Electrode Materials; Evaporation Slugs; High-Purity Metal Foils. Alternative Names: Palladium (powder),Palladium black,Palladium element. CAS No. 7440-5-3. IUPAC Name: palladium. Molecular Weight: 106.42. Molecular Formula: Pd. SMILES: [Pd]. | |
Palladium Quick inquiry Where to buy Suppliers range | Palladium and its alloys are used for hydrogen purification in fuel cells. Energy dispersive x-ray diffraction during electrochemical loading of palladium foils with hydrogen and deuterium was studied. Palladium foil was tested as a catalyst for Suzuki-Miyaura cross coupling reaction. Uses: Among the platinum group metals, palladium is the least noble metal, exhibiting greater reactivity than other metals of the group. The metal forms mostly bivalent compounds, although a small number of tetravalent and a fewer trivalent compounds are known. Palladium exhibits a strong tendency to form complexes, most of which are four-coordinated square planar complexes of the metal in +2 oxidation state. When heated in air or oxygen above 350°C, palladium forms a black oxide, PdO coated over its surface. On further heating to over 790°C, the oxide decomposes back to the metal. Palladium dissolves more oxygen in molten state than in solid form. Palladium reacts with fluorine and chlorine at 500°C forming its halides, the black PdF3 and the red deliquescent solid PdCl2. Palladium is attacked by concentrated nitric acid, particularly in the presence of nitrogen oxides. The reaction is slow in dilute nitric acid. Finely divided palladium metal reacts with warm nitric acid forming palladium(II) nitrate, Pd(NO3)2. Hydrochloric acid has no affect on the metal. Reaction with boiling sulfuric acid yields palladium sulfate, PdSO4, and sulfur dioxide. Palladium readily dissolves in aqua regia forming chloropalladic acid, H2PdCl6. Evaporation of this solution yields palladium(II) chloride, PdCl2. Palladium absorbs hydrogen over 800 times its own volume over a range of temperature. By doing so, the metal swells, becoming brittle and cracked. Such absorption of hydrogen decreases the electrical conductivity of the metal. Also, such absorption activates molecular hydrogen, dissociating it to atomic hydrogen. Group: Electrode Materials; Evaporation Slugs; High-Purity Metal Foils. Alternative Names: Palladium (powder),Palladium black,Palladium element. CAS No. 7440-5-3. IUPAC Name: palladium. Molecular Weight: Pd. Molecular Formula: 106.42. SMILES: [Pd]. Density: 12.02 g/cu cm. | |
Palladium black Quick inquiry Where to buy Suppliers range | surface area 40-60 m2/g, 99.95% trace metals basis. Uses: For analytical and research use. Group: Fuel Cell Catalysts. CAS No. 7440-5-3. Pack Sizes: 1G, 5G. Mole weight: 106.42. EC Number: 231-115-6. Catalog: AP7440053-A. Assay: 99.95% trace metals basis; reaction type: Heck Reaction; reaction type: Hiyama Coupling; reaction type: Negishi Coupling; reaction type: Sonogashira Coupling; reaction type: Stille Coupling; reaction type: Suzuki-Miyaura Coupling; reagent type: catalyst. | |
Palladium single crystal disc, 10mm (0.39in) dia, 1-2mm (0.04-0.08in) thick, (110) orientation Quick inquiry Where to buy Suppliers range | Liquid dispersion. Group: Evaporation Materials; Single Crystals; Fuel Cell Catalysts. Alternative Names: palladium nanopowder suspension, aqueous palladium nanoparticle solution, palladium nanofluid. CAS No. 7440-5-3. Molecular Weight: 106.42. Molecular Formula: Pd. Boiling Point: Varies by solvent. Melting Point: Varies by solvent. Density: Varies by solvent. | |
Platinum cobalt on carbon Quick inquiry Where to buy Suppliers range | extent of labeling: 30 wt. % Pt3Co loading. Uses: For analytical and research use. Group: Fuel Cell Catalysts. Pack Sizes: 1G. Mole weight: 644.17. Catalog: LS72339. | |
Platinum Ruthenium Foil Quick inquiry Where to buy Suppliers range | Platinum Ruthenium on Carbon Black, Platinum Ruthenium Alloy on Graphitized Carbon or Platinum Ruthenium on High Surface Area Advanced Carbon Support is a catalyst with numerous applications including organic chemistry, fuel cell technology, and the production of hydrogen via bioethanol reforming for alternative energy sources. Group: Catalysts. Grades: 99%|99.9%|99.99%|99.999%. CAS No. 172515-31-0. Product ID: ACM172515310. Molecular formula: PtRu. Mole weight: 296.154. Appearance: Foil powder. InChI: InChI=1S/Pt.Ru. InChIKey: CFQCIHVMOFOCGH-UHFFFAOYSA-N. | |
Platinum single crystal disc, 10mm (0.39in) dia, 1-2mm (0.04-0.08in) thick, (110) orientation, nominal Quick inquiry Where to buy Suppliers range | Gray solid. Uses: Silvery, whitish-gray, malleable, ductile metal. Mp: 1772?; bp: 2187?. Density: 21.45 g cm-3 at room conditions (very dense). Also shipped as a finely divided powder (platinum black), as a sponge, and as particles deposited on a supporting material such as alumina. Has strong catalytic activity in these forms; finely divided platinum can be dangerous to handle in the vicinity of other chemicals on this account. Used platinum catalysts are particularly dangerous and can be explosive.;OtherSolid;Solid;BLACK POWDER.;Silvery, whitish-gray, malleable, ductile metal.;Silvery, whitish-gray, malleable, ductile metal. Group: Fuel Cell Catalysts. Alternative Names: Platinum Nanoparticles on Titania Support. CAS No. 7440-6-4. IUPAC Name: platinum. Molecular Weight: 195.08g/mol. Molecular Formula: Pt. SMILES: [Pt]. InChI: InChI=1S/Pt. InChIKey: BASFCYQUMIYNBI-UHFFFAOYSA-N. Boiling Point: 6921 °F at 760 mm Hg (NIOSH, 2016);3825 ?;3827 ?;6921°F;6921°F. Melting Point: 3222 °F (NIOSH, 2016);1768.4 ?;1768.3?;1769 ?;3222°F;3222°F. Purity: 1% on Titania (Anatase) 1% on Titania (Rutile) 10% on Titania (Anatase) 10% on Titania (Rutile). Density: 21.45 (NIOSH, 2016);21.447 (calc);21.45 g/cm³;21.45;21.45. Solubility: Insoluble (NIOSH, 2016);Soluble in aqua regia. Insoluble in mineral and organic acids.;Solubility in water: insoluble;Insoluble. | |
Reduced Graphene Oxide Powder, decorated with Palladium Nanoparticles Quick inquiry Where to buy Suppliers range | Reduced Graphene Oxide (RGO) Powder decorated with Palladium Nanoparticles is graphene-metal hybrid material composed of reduced graphene oxide (r-GO) and a broad distribution of nanoscale palladium particles. Applications include electron microscopy imaging and as a catalyst material in fuel cells. Uses: Electrocatalyst. Field-effect transistors. Sensors. Lithium ion batteries. Supercapacitors. Group: Catalysts. Alternative Names: RGO-Pd, reduced graphene oxide nanosheets decorated with Pd NPs. Product ID: ACMA00018474. Molecular formula: CxOzyHz. Appearance: Powder. | |
Ruthenium Nanoparticle Dispersion Quick inquiry Where to buy Suppliers range | solid. Uses: Solid. Group: Fuel Cell Catalysts. Alternative Names: Ruthenium nanopowder suspension, aqueous Ruthenium nanoparticle solution, Ruthenium nanofluid. CAS No. 7440-18-8. IUPAC Name: ruthenium. Molecular Weight: 101.1g/mol. Molecular Formula: Ru. SMILES: [Ru]. InChI: InChI=1S/Ru. InChIKey: KJTLSVCANCCWHF-UHFFFAOYSA-N. Boiling Point: 4150 °C. Melting Point: 2334?. Purity: 99%, 99.9%, 99.99%, 99.999%. | |
Ruthenium on carbon Quick inquiry Where to buy Suppliers range | extent of labeling: 5 wt. % loading. Uses: For analytical and research use. Group: Fuel Cell Catalysts. Pack Sizes: 25G, 100G. Mole weight: 101.07. Catalog: LS72314. | |
Strontium Iridium Oxide Quick inquiry Where to buy Suppliers range | Strontium Iridium Oxide is a recently developed, highly efficient perovskite catalyst material for the oxygen evolution reaction (OER) required for renewable energy sources such as fuel cells and rechargeable batteries. Group: Catalysts. Alternative Names: Strontium-iridium oxide, Strontium iridium trioxide, Strontium iridate, Sr2IrO4, IrO3Sr0.85, Sr3IrO7, Sr-Ir-O, IrOx/SrIrO3, SrIO, Srn+1IrnO3n+1. Product ID: ACMA00024246. Molecular formula: SrIrO3 / Sr2IrO4 / Sr3IrO7. Mole weight: 327.84. Appearance: Crystalline solid or sputtering target. | |
Vanadium(III) oxide Quick inquiry Where to buy Suppliers range | Vanadium(III) oxide. Uses: Vanadium trioxide appears as a black crystalline solid. Density 4.87 g / cm3. Slightly soluble in water. Irritating to skin and eyes. May be toxic by ingestion. Used to make other chemicals. Used as a catalyst.;DryPowder;BLACK POWDER. Group: Electrode Materials; Solid Oxide Fuel Cell Materials. CAS No. 1314-34-7. IUPAC Name: oxo(oxovanadiooxy)vanadium. Molecular Weight: 149.881g/mol. Molecular Formula: V2O3;V2O3;O3V2. SMILES: O=[V]O[V]=O. InChI: InChI=1S/3O.2V. InChIKey: KFAFTZQGYMGWLU-UHFFFAOYSA-N. Boiling Point: Approximately 3000 ?. Melting Point: 1940 ?;1970 ?. Density: 4.87 g/cu cm;4.87 g/cm³. Solubility: In water, 0.01 g/100 mL at 20 ?;Insoluble in water;Slightly soluble in cold water (20-25 ?), soluble in hot water;Difficultly soluble in acids;Soluble in nitric acid, hydrogen fluoride, alkali.;Solubility in water, g/100ml at 20 ?: 0.01 (very poor). |