What is the Platinum?

Platinum is Black Powder, while it's Molecular Formula is Pt. Black Powder Used in Jewelry Industry: Platinum is utilized as a precious metal in the creation of high-quality jewelry due to its durability, hypoallergenic properties, and lustrous appearance. Used in Automotive Industry: Platinum is employed as a key component in catalytic converters for vehicles, where it facilitates the reduction of harmful emissions by converting toxic gases into less harmful substances before they are released into the atmosphere. Used in Industrial Applications: This versatile metal is used in various industrial applications, including the production of electrical contacts, resistance wires, and high-temperature furnaces, owing to its excellent thermal and electrical conductivity, as well as its resistance to corrosion. Used in Chemical and Pharmaceutical Production: Platinum is used as a catalyst in the manufacturing of various chemical and pharmaceutical compounds, capitalizing on its ability to initiate or accelerate chemical reactions without being consumed in the process. Used in Financial Markets: Recognized as a valuable commodity, platinum is traded in the financial markets and is often included in investment portfolios for its potential to retain value and hedge against economic volatility.

What is the CAS number for Platinum?

The CAS number of Platinum is 7440-06-4.

What is Platinum (7440-06-4) used for?

Platinum, with the chemical symbol Pt and atomic number 78, is a dense, malleable, and ductile metal characterized by its silvery-white color. It is renowned for its exceptional resistance to corrosion, high melting point, and electrical conductivity. This chemical element is not only a staple in the jewelry industry but also plays a pivotal role in automotive catalytic converters and a myriad of industrial applications. Platinum's unique properties, coupled with its scarcity, render it a highly coveted material across various sectors.InChI:InChI=1/Pt

Platinum

Base Information

PRODUCT:Platinum
CAS.:7440-06-4
MF:Pt
Molecular Weight:195.08
Purity:99%

Product Details

CAS： 7440-06-4

MF： Pt

Appearance： Black Powder

Buy Good Quality Platinum 7440-06-4 with a minimum purity of 99%

Molecular Formula:Pt
Molecular Weight:195.08
Appearance/Colour:Black Powder
Melting Point:1772 °C(lit.)
Refractive Index:n20/D 1.347
Boiling Point:3827°C(lit.)
Flash Point:3825 °C
PSA：0.00000
Density:1.060 g/mL at 20 °C
LogP:-0.00250

Platinum(Cas 7440-06-4) Usage

General Description

Platinum is a chemical element with the symbol Pt and atomic number 78. It is a dense, malleable, and ductile metal with a silvery-white color. Platinum is commonly used in jewelry, and is also a key component in catalytic converters in vehicles, as well as in various industrial applications. It is known for its resistance to corrosion, high melting point, and ability to conduct electricity. Platinum is also used in the production of various chemical and pharmaceutical compounds, and is a valuable commodity in the financial markets. Its scarcity and unique properties make it a highly sought-after material in various industries.

InChI:InChI=1/Pt

7440-06-4 Relevant articles

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This article focuses on the dependence o...

Fabrication and evaluation of platinum/diamond composite electrodes for electrocatalysis: Preliminary studies of the oxygen-reduction reaction

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A catalytic electrode was prepared using...

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Temperature effect on the electrode kinetics of ethanol oxidation on Pd modified Pt electrodes and the estimation of intermediates formed in alkali medium

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Ethanol has been recognized as the ideal...

Platinum Electroless Deposition on Silicon from Hydrogen Fluoride Solutions: Electrical Properties

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, p. C528-C532 (2001)

Current transport through mesa structure...

In situ FTIR spectroscopic studies of (bi)sulfate adsorption on electrodes of Pt nanoparticles supported on different substrates

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The reaction of granulated CaO sorbent w...

Light-driven synthesis of hollow platinum nanospheres

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Hollow platinum nanospheres that are por...

Porous platinum mesoflowers with enhanced activity for methanol oxidation reaction

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Porous Pt and Pt-Ag alloy mesoflowers (M...

Promotion effects in the oxidation of CO over zeolite-supported Pt nanoparticles

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, p. 3822 - 3831 (2005)

Well-defined Pt-nanoparticles with an av...

Structure and morphology of catalysts produced via oxidation of Mo-Pt alloys

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, p. 264 - 270 (2009)

A novel approach has been proposed for p...

Pt-Ru electrodeposited on gold from chloride electrolytes

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, p. 2775 - 2784 (2007)

Voltammetric behavior of submicron-thick...

Rational synthesis of Pt spheres with hollow interior and nanosponge shell using silica particles as template

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, p. 3885 - 3887 (2011)

Here we report a facile and efficient me...

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, p. 2773 - 2777 (2011)

Many facets: A simple synthetic route, w...

Kinetic studies of the stability of Pt for NO oxidation: Effect of sulfur and long-term aging

Pazmino, Jorge H.,Miller, Jeffrey T.,Mulla, Shadab S.,Nicholas Delgass,Ribeiro, Fabio H.

, p. 13 - 24 (2011)

The stability of Pt catalysts for NO oxi...

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, p. 215 - 218 (2005)

Layered double hydroxides (LDH) supporte...

Gas-phase kinetics of ground-state platinum with O2, NO, N2O and CH4

Campbell, Mark L.

, p. 353 - 358 (1998)

The gas-phase reactivity of ground-state...

Electrochemical properties of Pt coatings on Ni prepared by atomic layer deposition

Hoover, Robert R.,Tolmachev, Yuriy V.

, p. A37-A43 (2009)

Presented herein is an approach to fabri...

Integrated structural control of cage-type mesoporous platinum possessing both tunable large mesopores and variable surface structures by block copolymer-assisted Pt deposition in a hard-template

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Cage-type mesoporous Pt with tunable lar...

Support effects on the oxidation of ethanol at Pt nanoparticles

Moghaddam, Reza B.,Pickup, Peter G.

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The effects of metal oxide supports on e...

Pulsed galvanostatic deposition of Pt particles on microcrystalline and nanocrystalline diamond thin-film electrodes I. Characterization of as-deposited metal/diamond surfaces

Bennett, Jason A.,Show, Yoshiyuki,Wang, Shihua,Swain, Greg M.

, p. E184-E192 (2005)

The pulsed galvanostatic deposition of n...

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, p. 18543 - 18547 (2009)

A facile, reliable, general, and robust ...

Area-selective atomic layer deposition of platinum on YSZ substrates using microcontact printed SAMs

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, p. D648-D656 (2007)

Using (methylcyclopentadienyl)trimethylp...

Microgravity effects on the electrochemical oxidation of ammonia: A parabolic flight experiment

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The diffusion of molecular species throu...

Addition of Hydroxide, Alkoxide, and Carboxylate Anions to Platinum-bonded Ethylene

Fanizzi, Francesco P.,Intini, Francesco P.,Maresca, Luciana,Natile, Giovanni,Gasparrini, Francesco

, p. 1019 - 1022 (1990)

The cation 2-C2H4)Cl(tmen)>+ (1) (tmen=N...

Photosensitised Oxidation of Water by CdS-based Suspensions

Mills, Andrew,Williams, Geraint

, p. 503 - 520 (1989)

Dispersions of CdS powder with or withou...

Oxygen reduction at platinum modified gold electrodes

Van Brussel,Kokkinidis,Hubin,Buess-Herman

, p. 3909 - 3919 (2003)

The reduction of oxygen has been studied...

Synthesis and X-ray crystal structures of bis(oxazolinyl)phenyl-derived chiral palladium(II) and platinum(II) and -(IV) complexes and their use in the catalytic asymmetric aldol-type condensation of isocyanides and aldehydes

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, p. 3408 - 3416 (2002)

The transmetalation of (Phebox)SnMe3 (3;...

Comparison of extended x-ray absorption fine structure and Scherrer analysis of x-ray diffraction as methods for determining mean sizes of polydisperse nanoparticles

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Curve fitting of extended x-ray absorpti...

A new stacking variant of Na2Pt(OH)6

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X-ray structure and multinuclear NMR studies of platinum(II) complexes with 5-methyl-1,2,4-triazolo[1,5-a]pyrimidin-7(4H)-one

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New dichloride platinum(II) complexes wi...

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In a search for electrocatalysts based o...

Vapor-deposited Pt and Pd-Pt catalysts for solid acid fuel cells: Short range structure and interactions with the CsH2PO4 electrolyte

Papandrew, Alexander B.,John, Samuel St.,Elgammal, Ramez A.,Wilson, David L.,Atkinson, Robert W.,Lawton, Jamie S.,Arruda, Thomas M.,Zawodzinski, Thomas A.

, p. F464 - F469 (2016)

State-of-the-art cathodes for solid acid...

Electro-oxidation of some phenolic compounds by electrogenerated O 3 and by direct electrolysis at PbO2 anodes

Amadelli, Rossano,Samiolo, Luca,Battisti, Achille De,Velichenko, Alexander B.

, p. P87-P92 (2011)

The oxidative degradation of phenolic co...

Specific features of the formation of Pt(Cu) catalysts by galvanic displacement with carbon nanowalls used as support

Podlovchenko,Krivchenko,Maksimov,Gladysheva,Yashina,Evlashin,Pilevsky

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Microamounts of Cu are applied by the me...

Scanning tunneling microscopy study of platinum deposited on graphite by metalorganic chemical vapor deposition

Ngo,Brandt,Williams,Kaesz

, p. 411 - 417 (1993)

The growth of thin Pt(111) films on high...

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Mahmoud, Walaa H.,Mohamed, Gehad G.,Mahmoud, Nessma F.

, (2017)

Three new binary and ternary metal compl...

Preferential CO oxidation promoted by the presence of H2 over K-Pt/Al2O3

Minemura, Yuji,Ito, Shin-Ichi,Miyao, Toshihiro,Naito, Shuichi,Tomishige, Keiichi,Kunimori, Kimio

, p. 1429 - 1431 (2005)

In preferential CO oxidation in H2-rich ...

Electrochemical deposition of platinum on fluorine-doped tin oxide: The nucleation mechanisms

Ko, Young-Seon,Kwon, Young-Uk

, p. 7276 - 7281 (2010)

We report the electrochemical formation ...

One-pot synthesis of PtSn bimetallic composites and their application as highly active catalysts for ethanol electrooxidation

Feng, Yue,Wang, Caiqin,Bin, Duan,Zhai, Chunyang,Ren, Fangfang,Yang, Ping,Du, Yukou

, p. 93 - 99 (2016)

PtSn nanoparticles with different molar ...

Catalyst Architecture for Stable Single Atom Dispersion Enables Site-Specific Spectroscopic and Reactivity Measurements of CO Adsorbed to Pt Atoms, Oxidized Pt Clusters, and Metallic Pt Clusters on TiO2

DeRita, Leo,Dai, Sheng,Lopez-Zepeda, Kimberly,Pham, Nicholas,Graham, George W.,Pan, Xiaoqing,Christopher, Phillip

, p. 14150 - 14165 (2017)

Oxide-supported precious metal nanoparti...

Catalytic oxidation of carbon monoxide over radiolytically prepared Pt nanoparticles supported on glass

Kapoor,Belapurkar,Mittal,Mukherjee

, p. 1654 - 1661 (2005)

Platinum nanoparticles have been prepare...

Pt, PtNi and PtCoNi film electrocatalysts prepared by chemical vapor deposition for the oxygen reduction reaction in 0.5 M KOH

García-Contreras,Fernández-Valverde,Vargas-García

, p. S425-S428 (2010)

Pt, PtNi and PtCoNi films were deposited...

Asymmetrically strained hcp rhodium sublattice stabilized by 1D covalent boron chains as an efficient electrocatalyst

Li, Zhenyu,Ai, Xuan,Chen, Hui,Liang, Xiao,Li, Xiaotian,Wang, Dong,Zou, Xiaoxin

supporting information, p. 5075 - 5078 (2021/05/28)

Intermetallic rhodium boride (RhB) compr...

Reactions of organoplatinum complexes with dimethylamine-borane

Puddephatt, Richard J.,Robinson, Shawn

, p. 14965 - 14972 (2021/09/04)

The reactions of dimethylamine-borane wi...

New perspective of a nano-metal preparation pathway based on the hexahydro-closo-hexaborate anion

Liu, Jun,Zhang, Haibo,Zhao, Xue

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Today, metal-based nanomaterials play an...

Intermetallic Nanocatalysts from Heterobimetallic Group 10-14 Pyridine-2-thiolate Precursors

Adamson, Marquix A. S.,Chen, Yunhua,Daniels, Carena L.,Dorn, Rick W.,Fan, Huajun,Knobeloch, Megan,Rossini, Aaron J.,Vela, Javier,Wu, Hao,Yox, Philip,Zhou, Guoquan

supporting information, (2020/03/13)

Intermetallic compounds are atomically o...

7440-06-4 Process route

: dihydrogen hexachloroplatinate

: 13494-80-9,7783-09-7
hydrogen telluride

: 14683-12-6
tellurium

: 10026-07-0
tellurium tetrachloride

: 7440-06-4
platinum

Conditions

Conditions	Yield
In water;
In water;

: 12034-41-2
disodium telluride

: 13454-96-1
platinum(IV) chloride

: 10026-07-0
tellurium tetrachloride

: 7440-06-4
platinum

Conditions

Conditions	Yield
In not given;
In not given;

7440-06-4 Upstream products

1314-15-4
platinum(IV) oxide
64-18-6
formic acid
13454-96-1
platinum(IV) chloride
26035-31-4
cisplatine

7440-06-4 Downstream products

156732-15-9
(2S,3S,5S)-2-(N,N-dibenzylamino)-3-hydroxy-5-amino-1,6-diphenylhexane
57682-11-8
N-acetyl-2-(2,3-epoxypropoxy)aniline
152146-59-3
2-n-butyl-1-[(4-carboxyphenyl)-methyl]-1H-imidazole-5-carboxaldehyde
58373-46-9
(2R₃R,2S₃S)-cis-2-phenylpiperidin-3-amine

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