Platinum dioxide
[CAS# 1314-15-4]

Identification

• Classification: Inorganic chemical industry >> Inorganic salt >> Oxides of rare earth metals, yttrium or scandium
• Name: Platinum dioxide
• Synonyms: Platinum(IV) dioxide; Adams' catalyst
• Molecular Formula: PtO₂
• Molecular Weight: 227.08
• CAS Registry Number: 1314-15-4
• EC Number: 215-223-0
• SMILES: O=[Pt]=O

Properties

• Melting point: 450 ºC (Expl.)

Safety Data

• Hazard Symbols: GHS03;GHS07 DangerGHS03
• Hazard Statements: H271-H272-H319
• Precautionary Statements: P210-P220-P264+P265-P280-P283-P305+P351+P338-P306+P360-P337+P317-P370+P378-P371+P380+P375-P420-P501

Hazard Classification

Hazard	Class	Category Code	Hazard Statement
Oxidising solids	Ox. Sol.	1	H271
Oxidising solids	Ox. Sol.	2	H272
Eye irritation	Eye Irrit.	2	H319
Oxidising solids	Ox. Sol.	3	H272
Skin irritation	Skin Irrit.	2	H315
Chronic hazardous to the aquatic environment	Aquatic Chronic	3	H412
Serious eye damage	Eye Dam.	1	H318

• Transport Information: UN 1479

Discovory and Applicatios

Platinum dioxide, commonly referred to as Adams' catalyst, is a platinum-based inorganic compound with the approximate empirical formula PtO₂. It exists as a dark brown to black powder and is best known for its role as a highly effective hydrogenation catalyst in organic synthesis. The compound is typically prepared by the controlled oxidation of chloroplatinic acid (H₂PtCl₆) or other platinum salts in the presence of oxygen or ozone, often followed by drying and activation steps to produce the active catalytic form.

The discovery of platinum dioxide as a catalyst dates back to the work of Roger Adams in the 1920s. Adams demonstrated that when chloroplatinic acid was treated under certain conditions, it yielded a finely divided platinum oxide with exceptional catalytic properties for hydrogenation. This catalyst could hydrogenate a variety of unsaturated organic compounds efficiently and under mild reaction conditions. The term "Adams' catalyst" thus became synonymous with platinum dioxide used for catalytic hydrogenation.

Structurally, platinum dioxide is often described as amorphous or poorly crystalline. It consists of platinum atoms in a high oxidation state coordinated to oxygen atoms. Upon activation, typically by heating under a hydrogen atmosphere, platinum dioxide is reduced to finely dispersed metallic platinum supported on an oxide matrix. This activated form provides a large surface area of highly reactive platinum sites, which facilitates hydrogen adsorption and transfer to organic substrates.

The most prominent application of platinum dioxide is in heterogeneous catalytic hydrogenation. It is widely employed in both academic laboratories and industrial processes to reduce alkenes, alkynes, aromatic rings, nitro compounds, carbonyl groups, and other unsaturated functionalities. Its broad substrate scope and high selectivity have made it a staple catalyst for the synthesis of pharmaceuticals, agrochemicals, and fine chemicals.

Beyond simple hydrogenation, platinum dioxide can catalyze more complex transformations, including hydrogenolysis and reductive amination. It is compatible with a variety of solvents and reaction conditions, often showing tolerance toward functional groups sensitive to other catalytic systems. This robustness has led to its use in multi-step synthetic sequences and in the preparation of enantiomerically pure compounds when combined with chiral modifiers.

In addition to organic synthesis, platinum dioxide has found application in environmental and energy-related fields. It is used as a catalyst in fuel cells and in the catalytic converters of automobiles, where it aids in the reduction of harmful exhaust gases. The catalyst’s ability to facilitate oxidation and reduction reactions under mild conditions makes it valuable for these applications.

Handling and storage of platinum dioxide require care due to the pyrophoric nature of finely divided platinum catalysts. Exposure to air, particularly in dry and finely divided form, may lead to spontaneous ignition. Therefore, it is generally stored under inert atmosphere or as a wet paste, and activation is conducted under controlled hydrogen flow with temperature regulation.

From an environmental and economic perspective, platinum dioxide represents a precious metal catalyst with high activity but also high cost. Efforts to improve catalyst efficiency, recycling, and to develop supported platinum catalysts with lower metal loading continue to be important areas of research. Additionally, advances in nanoparticle synthesis and catalyst design aim to enhance activity while minimizing platinum usage.

In summary, platinum dioxide is a key platinum-based catalyst known for its role in hydrogenation reactions since its discovery by Roger Adams. Its activation to a finely divided metallic platinum surface imparts exceptional catalytic properties, enabling a wide range of chemical transformations. The compound’s stability, versatility, and effectiveness have made it invaluable in both laboratory and industrial settings. Ongoing research continues to optimize its use in sustainable and efficient catalytic processes.