Technical articles

How to Select and Use Platinum Catalysts: A Complete Guide to Homogeneous, Heterogeneous, and Electrocatalysis (with an Aladdin Catalog No. Cross-Reference Table)

What Is a Platinum Catalyst?

A platinum (Pt) catalyst refers to a catalytic material or catalytic system that uses platinum (Pt) as the active center to significantly lower the activation energy of a reaction, thereby increasing reaction rate and selectivity. It can be either:

  1. Homogeneous catalyst: Platinum is dissolved in the reaction system as molecules/complexes (e.g., platinum catalysts commonly used for hydrosilylation/silicon–hydrogen addition in the organosilicon industry). It is especially critical in “addition-cure” systems such as silicone rubber, adhesives, and electronic encapsulation.
  2. Heterogeneous catalyst: Platinum is present as metal nanoparticles or oxides supported on a carrier, and is widely used in hydrogenation, dehydrogenation, redox reactions, as well as electrocatalysis.
  • Supported type: Pt/support (Pt/C, Pt/AlO, Pt/SiO, )
  • Unsupported powders/oxides: Pt black, Pt sponge, PtO (Adams catalyst), etc. (PtO is often a precatalyst)

Term

One-sentence explanation

Typical form

Where it is used

Homogeneous Pt catalyst

Dissolves in the reaction medium; catalysis proceeds via a molecular-level Pt active center cycling through elementary steps

Pt complex solution

Hydrosilylation; addition curing of silicone rubber

Heterogeneous Pt catalyst

Pt catalyzes on solid surface sites and can be filtered and recovered after reaction

Pt/C, Pt/AlO, Pt black, etc.

Hydrogenation, dehydrogenation, redox reactions

Pt metal source/precursor

Not necessarily “directly catalytic,” but can be reduced/deposited or undergo ligand exchange to generate active Pt

HPtCl, KPtCl, PtCl, etc.

Preparing supported catalysts / in situ generation of active species

You can think of “platinum catalysts” as a family: although they are all called “Pt catalysts,” differences in form (homogeneous/heterogeneous/electrocatalytic), oxidation state (Pt(0)/Pt(II)/Pt(IV)), and ligands/supports can lead to completely different performance and application scenarios.

What Makes Platinum Catalysts “Special”?

Platinum has remained a “top performer” in catalysis mainly for three reasons:

1. Strong interactions with key small molecules/bonds and reversible activation capability

  • Pt can efficiently adsorb and activate substrates such as H, alkenes, and alkynes. In homogeneous systems, Pt centers can also form new bonds efficiently through typical organometallic steps such as oxidative addition–migratory insertion–reductive elimination. In hydrosilylation, for example, the classic Chalk–Harrod mechanism represents such an “organometallic catalytic cycle.”

2. High selectivity and mild conditions

  • In the organosilicon industry, Pt-catalyzed hydrosilylation (addition of Si–H across C=C) is the core reaction for forming Si–C bonds and achieving crosslinking/curing. This reaction “hardly proceeds without a catalyst, but with an appropriate Pt catalyst it can be completed rapidly under mild conditions,” making it one of the industrial standard approaches.

3. A toolbox enabled by ligand/support engineering

  • Even for the same hydrosilylation, Speier’s catalyst (a chloroplatinic-acid-based system) and Karstedt’s catalyst (a Pt(0) system with vinyl-siloxane ligands) each have advantages in solubility, activity, controllability, and side reactions. In practice, inhibitors can be used to create a time window such as “no reaction at room temperature, curing only upon heating.”

Are Platinum Catalysts Important?

Yes—platinum catalysts are “key enabling technologies” in multiple industries.

  1. In the organosilicon industry, Pt-catalyzed hydrosilylation is the core pathway for forming Si–C bonds and enabling addition curing, and is considered one of the highly relied-upon key processes in this industry.
  2. In hydrogen energy and fuel cells, Pt-based electrocatalysis remains one of the mainstream routes (also driving a wave of research on “reducing Pt usage and improving durability”).
  3. Without a catalyst: slow reactions, harsh conditions, more side reactions, and difficult scale-up
  4. With an appropriate Pt catalyst: fast completion under mild conditions, good selectivity, a designable process window (inhibition/heat-triggering), and stronger reproducibility

How to Understand Pt-Catalyzed Mechanisms

A. Homogeneous: Think of It as “a Metal Center Running a Cycle”

Using Pt-catalyzed hydrosilylation (Si–H addition) as an example, the classic Chalk–Harrod (and modified) models can be understood by the sequence “coordination → oxidative addition → migratory insertion → reductive elimination” (a simplified description intended to capture the logic of the catalytic cycle).

  1. Oxidative addition of Si–H to Pt (Pt inserts into Si–H to form Pt–H / Pt–Si)
  2. Migratory insertion of the alkene (alkene inserts into the Pt–H bond)
  3. Reductive elimination to form a new Si–C bond, releasing the product and regenerating a Pt species that can continue catalysis

Key step

What happens

Observable implications / significance

Oxidative addition

Pt “splits” Si–H to form Pt–H / Pt–Si

Generates reactive intermediates that can proceed further

Migratory insertion

Alkene inserts into Pt–H (or related bond)

Determines regioselectivity and reaction rate

Reductive elimination

Forms the Si–C bond; Pt returns to a catalytically competent state

Product formation; catalytic cycle closes

Note: Common industrial “inhibitors” can be understood as follows: they temporarily occupy/passivate Pt active sites, preventing rapid crosslinking at low temperature. Heating typically changes the coordination equilibrium/dissociation rate between the inhibitor and Pt, or leads to inhibitor consumption, so that the system exhibits “controllably triggered accelerated curing.” Studies on inhibition mechanisms (e.g., β-alkynols) indicate that temperature and functional-group selectivity are key factors.

B. Heterogeneous/Electrocatalysis: Think of It as “Surface Sites Doing Adsorption–Reaction–Desorption”

For Pt/C, Pt black, Pt/AlO, etc., the key points are:

  1. Activity originates from surface sites (in general, larger specific surface area and better metal dispersion often lead to higher activity)
  2. Reactions usually proceed through: substrate adsorption → surface activation/transformation → product desorption
  3. In electrocatalysis (fuel cells/water electrolysis), the site structure and adsorption strength of surface intermediates determine overpotential, durability, and poisoning resistance. Pt/C is commonly used as a fuel-cell electrocatalyst material.

One-line flow diagram for heterogeneous mechanisms:

Substrate diffusion to the surface → adsorption (site occupation) → surface activation / bond formation or bond cleavage → product desorption → site regeneration

Platinum Catalysts and Related Products: How to Classify Products

Primary category

Secondary category

Representative form

Typical use

Advantages

Common limitations

Activation/pretreatment essentials

Recovery/handling recommendations

Key specifications

Direct Pt catalysts

Homogeneous hydrosilylation / addition curing

Pt(0) complex solutions; modified Pt(0); in situ activation systems from Pt sources

Hydrosilylation, silicone gel addition curing, crosslinking

High activity; process window possible (with inhibitors)

Sensitive to inhibition/poisoning; overdosing may cause runaway

Usually no pretreatment; pay attention to addition order, thorough mixing, temperature control

Collect Pt-containing residues for centralized recovery; follow enterprise/lab disposal rules

Pt concentration/unit; solvent system; controllability (pot life); impurity control

Direct Pt catalysts

Supported heterogeneous (general hydrogenation)

Pt/C, Pt/AlO, Pt/SiO, PtO, etc.

Hydrogenation/reduction; dehydrogenation/redox (system-dependent)

Easy separation; recyclable; suitable for scale-up

Mass-transfer limitations; batch variability; easily poisoned

Pre-reduction/drying as needed; standardized pretreatment improves reproducibility

Filter and recover solids; calcination/regeneration possible (depending on system and regulations)

Pt loading (wt%); moisture content; support type/pore structure; particle size/dispersion; whether pre-reduced

Direct Pt catalysts

Specific selectivity / anti-poisoning type

S-modified Pt / Pt on S-doped supports / Pt–S related systems; modified-support Pt, etc.

Selective hydrogenation; special substrate systems

Better selectivity or tolerance

Highly application-specific; narrower operating window

Often requires specified activation steps (reduction/sulfidation conditions, etc.)

Handle solid waste/residues per SDS and regulations

Whether sulfidized; whether pre-reduced; support and promoters; moisture content

Electrocatalyst materials

Electrocatalysis-grade Pt/C

Pt/C (fuel-cell grade/electrocatalysis grade)

PEM fuel cells; general electrode research

Benchmark material; comparable datasets

Degradation (agglomeration/support corrosion)

For electrode prep, focus on ink formulation (solvent/ionomer) and ultrasonic dispersion

Collect remaining electrodes/slurries for centralized recovery

Particle size/dispersion; grade (FC grade); support type; Pt loading (wt%)

Electrocatalyst materials

Alloy/bimetallic electrocatalysts

PtRu/C, PtCo/C, PtCo/C, etc.

CO tolerance; tuning intermediate adsorption; ORR enhancement, etc.

Improved activity/tolerance

High demands on composition/preparation consistency

Electrode prep depends more strongly on formulation and process window

Same as above

Alloy composition; particle-size distribution; support stability; grade

Catalyst materials

Pt black / Pt sponge / nano-Pt

Pt black, sponge Pt, nanoparticles, colloids/dispersions

Heterogeneous catalysis, model studies, electrode fabrication, deposition/loading

High specific surface area (especially Pt black/nano-Pt)

Higher requirements for powder/colloid stability and safety

For nanosystems, consider dispersion medium and stabilizers; for powders, avoid dust and agglomeration

Collect residual powders/dispersions for Pt recovery

Particle size; dispersion medium; surfactant-free or not; purity (metals basis)

Catalyst precursors/metal sources

Inorganic salts/acids/standard solutions

Chloroplatinic acid and salts, chloroplatinite salts, platinum nitrate solutions, Pt halides, etc.

Preparing Pt/support catalysts, in situ reduction to Pt nanoparticles, starting materials for coordination synthesis

Flexible; suitable for impregnation/deposition; easy quantification

Usually not “directly catalytic”; needs reduction/deposition

Key variables: reductant, pH, temperature, chloride ions and washing, loading procedure

Collect Pt-containing solutions for centralized recovery; handle per corrosive/sensitization risk

Purity (metals basis); concentration; counter-anion system (Cl/NO₃⁻); water/solvent compatibility

Catalyst precursors/metal sources

Organometallic precursors

Pt(acac), Pt(hfac), Pt(II)/Pt(IV) organometallics, etc.

Thin films/nanomaterial preparation; specific ligation and activation

Suitable for materials processing

More “materials precursors” than general catalysts

Optimize by process (thermal decomposition/reduction/deposition)

Dispose residues per organometallic waste rules

Purity; metal content; volatility/solubility; process window

Analysis-dedicated catalysts

Pt catalysts for elemental analyzer combustion

Fixed-bed granules/packing

Combustion/oxidation in CHNS/O elemental analysis

Clear purpose; mature methodology

Different evaluation system from synthetic catalysis catalysts

Operate per instrument method and packing procedures

Replace/dispose consumables per regulations

Particle size; Pt content; compatible consumable specifications

Related materials (boundary note)

Electrode/structural materials

Pt foil/wire/alloy wire, conductive pastes, etc.

Electrodes/connections, thermocouples/high-temperature parts, conductive coatings

Corrosion-resistant; stable

Not the same as “catalyst”; catalytic function depends on structure/surface

Usually no activation required (but surface state affects electrochemical behavior)

High recycling value as precious metal materials

Form factor/dimensions; purity; alloy composition; processing state

Related materials (boundary note)

Analytical standards

Pt standard solutions/CRMs

Quantification in ICP/AA, etc.

Traceable; accurate

Not for catalysis

Concentration; acid matrix; certificate information

Common R&D/Lab Uses and “Selection Methods” — Application Scenario → Recommended Form → Typical Product Category

Application scenario

Recommended Pt catalyst form

Typical product category

Can be dosed directly?

Most critical specs

Common risks/notes

Organosilicon hydrosilylation / addition curing (silicone rubber, encapsulants, gels, etc.)

Homogeneous Pt catalysts (Pt(0) complexes or in situ activation from Pt sources)

Karstedt-type Pt(0) solutions; modified Pt(0) (e.g., NHC-stabilized); Speier-type systems (chloroplatinic acid in isopropanol, system/solution)

Usually yes (some systems generate active species in situ)

Pt concentration (mol/L or wt%); solvent/carrier (siloxanes/xylene, etc.); system controllability (pot life/inhibitor compatibility)

Susceptible to inhibition/poisoning (S/P/amines/alkynols, etc.); overdosing may cause runaway exotherm/side reactions; sensitive to mixing uniformity and temperature

Hydrogenation/reduction in organic synthesis (common in labs)

Supported heterogeneous Pt

Pt/C; Pt/AlO; Pt/SiO; PtO (Adams type)

Yes

Pt loading (wt%); moisture content (wet cake/dry powder); support type; dispersion/specific surface area; need for pre-reduction

Easily poisoned by S/P/strongly coordinating impurities; activity fluctuations due to moisture/pretreatment differences; pay attention to filtration, stirring/mass transfer, and hydrogen safety

Selective hydrogenation / anti-poisoning needs (more process/scale-up oriented)

Supported heterogeneous Pt (modified/sulfidized if needed)

Sulfidized Pt/C; Pt on specific supports (carbon/alumina/silica, etc.)

Yes (may require activation)

Whether “pre-reduced/pre-sulfidized”; support and promoters; moisture and storage form

Selectivity depends on system and pretreatment; sulfidized catalysts have higher requirements for operation/disposal (per SDS)

Oxidation / catalytic combustion (CO/VOCs environmental and process oxidation)

Supported heterogeneous Pt

Pt/AlO, Pt/SiO, Pt black, etc. (engineering often uses fixed-bed/coated forms)

Yes

Support heat resistance/pore structure; Pt dispersion; presence of promoters; formed shape (powder/pellet/coating)

Sintering deactivation at high temperature; sulfur/halogens easily poison; manage bed pressure drop and thermal management

Dehydrogenation / reforming / petrochemical applications (macroscopically important)

Supported heterogeneous Pt (often with promoters/acidic supports)

Pt/AlO types (industrial systems are often composite formulations)

Often usable as supplied (highly application-specific formulations)

Form factor and promoter system; heat resistance/anti-sintering; regeneration method

Highly system-specific; regeneration conditions are critical; impurities (S/Cl/water) greatly affect performance

Electrocatalysis (fuel cells/electrode research/electrolysis)

Electrocatalysis-grade Pt nano/alloys + conductive supports

Pt/C (electrocatalysis grade); PtRu/C; PtCo/C; Pt black (fuel-cell grade); Pt-graphene/composites

Yes (for electrode/catalyst-layer fabrication)

Particle size/dispersion; ECSA/surface-area indicators (if available); support stability; alloy composition; grade (fuel-cell grade)

Sensitive to impurities (especially CO/S); degradation from support corrosion/particle agglomeration; match solvent/ionomer system

Elemental analysis / combustion analysis (common “Pt catalyst” request)

Fixed-bed granular Pt catalytic packing

Pt catalysts for elemental analysis (various Pt contents and particle sizes)

Yes

Particle size and bed packing; Pt content; instrument/consumable compatibility

Different from organic-synthesis catalysts; instrument method/consumable specifications are more important

Preparing supported Pt / nano-Pt (catalyst preparation routes)

Pt precursors/metal sources (solutions or salts)

Chloroplatinic acid and salts; chloroplatinite salts; platinum nitrate solutions; Pt halides, etc.

Usually no (needs reduction/deposition/activation)

Purity (metals basis); concentration (standard solutions preferred); anion type (Cl/NO₃⁻, etc.); water/solvent system

“No reaction after addition” often due to being only a precursor; reduction conditions and residual chloride affect performance; handle corrosive/sensitization risks per SDS

Thin films/coatings/material deposition (research preparation)

Organometallic precursors/complexes

Pt(acac), Pt(hfac), specific Pt(II)/Pt(IV) organometallics, etc.

Usually no (primarily for preparation)

Volatility/solubility; purity; metal content; process window (temperature/atmosphere)

More like “materials precursors” than general catalysts; processing conditions determine film/particle morphology

Safety and Experimental Notes

Hazards vary widely among different Pt compounds/catalysts; always refer to the SDS. Only the most critical reminders are listed here:

  1. Chloroplatinic acid (hexachloroplatinic acid) is classified in some SDSs as corrosive, acutely toxic, and skin/respiratory sensitizing. Use appropriate PPE, avoid inhalation of dust/aerosols, and operate under ventilation.
  2. High-surface-area metal powders such as platinum black may show higher reactivity under certain conditions. Strictly follow the supplier’s SDS requirements for storage, transfer, and disposal. Avoid generating inhalable dust during filtration/drying; in hydrogenation systems, keep hydrogen isolated from ignition sources/heat and manage pyrophoricity/flammability risks (per the specific SDS).
  3. "Platinum is expensive": in experimental planning, it is recommended to incorporate “Pt recovery/centralized handling of Pt-containing residues” into the SOP.

Q&A

Q1: Does higher Pt content always mean better catalytic performance?

Not necessarily.

  1. Homogeneous: activity depends on the “Pt species available for the catalytic cycle.” Too high a loading may increase side reactions or cause an uncontrollably fast reaction.
  2. Heterogeneous: performance depends on surface area and dispersion. A 10 wt% Pt/C is not necessarily faster than a 5 wt% Pt/C; if particles are larger and dispersion is poorer, there may be fewer effective active sites.

Q2: Why do different brands/batches vary so much even if they are all called Pt/C?

  1. Because Pt/C has many key variables: support type, pore structure, Pt particle size, dispersion, reduction degree, moisture content, and residual additives can all affect activity and selectivity. Recommendations: lock the supply specification + lock the pretreatment procedure + run small-scale benchmarking.

Q3: Are chloroplatinic acid (Speier system) and Karstedt’s catalyst the same thing?

No.

  1. The chloroplatinic-acid system is more like a “Pt source + solvent/ligand environment” and often needs to form active species in situ.
  2. Karstedt-type catalysts are commonly used Pt(0) complex systems and, in practice, are more like “ready-to-use catalyst product forms.”

Q4: Why does my silicone addition-cure system sometimes “not cure at all”?

  1. A common cause is inhibition/poisoning: sulfur, phosphorus, amines, certain alkyne inhibitors, and even impurities in some additives may passivate Pt. A practical troubleshooting approach is “one-by-one raw-material exclusion”: first validate the base formulation + catalyst, then add additives one at a time.

Q5: Why do bubbles, yellowing, or side reactions occur after adding a Pt catalyst?

Possible causes:

  1. Excessive temperature or high local concentration leading to side reactions
  2. Activatable impurities in the formulation (e.g., certain unsaturated species, peroxides, sulfur-containing components)

Countermeasures: reduce dosage, optimize mixing order, use inhibitors/stepwise heating, improve raw-material purity.

Q6: How to choose between Pt black, Pt sponge, and nano-Pt dispersions?

  1. Pt black/nano-Pt: high specific surface area; suitable for electrocatalysis or model studies, but “more reactive” and requires more standardized handling.
  2. Pt sponge: coarser structure; often used in certain heterogeneous catalysis/high-temperature applications or as a material.
  3. Nano dispersions: good dispersion and easy for coatings/electrodes; pay attention to solvent systems, stabilizers, and long-term stability.

Q7: Are Pt foil/Pt wire considered “Pt catalyst-related”?

  • Strictly speaking, they are mainly materials for electrodes/thermocouples rather than “catalyst products.”
  • However, if your scenario is electrode fabrication, catalytic electrode supports, or corrosion-resistant conductors, they can be regarded as “catalysis-related materials.”

Q8: Do I have to use Pt for electrocatalysis? What is the logic of PtRu and PtCo?

Pt is still a benchmark material in many systems. Alloying (e.g., PtRu, PtCo) is often used to:

  1. Change intermediate adsorption strength and improve activity
  2. Improve poisoning resistance, durability, or specific reaction performance—while also bringing considerations of cost, stability, and preparation consistency.

Q9: Can I use a “Pt salt” directly as a catalyst?

  • Sometimes yes, but more often it is a precursor: it must be reduced/ligated/deposited in the system before it shows the expected catalytic performance. If “controllability and reproducibility” are required, it is generally recommended to choose a “direct catalyst form” (homogeneous solutions or mature supported catalysts).

Q10: Is a “purer” Pt catalyst always better?

  • For “trace-sensitive” research (electrocatalysis, ultra-low loading, precision organosilicon curing), higher purity is usually more stable. For general hydrogenation scale-up, specification consistency and repeatable pretreatment are often the key—purity is not the only variable.

Representative Aladdin Platinum Catalysts and Pt Source Products

The table below summarizes representative Aladdin platinum catalysts and Pt source products, covering two major groups—from ready-to-use catalyst forms to metal sources/precursors used for catalyst preparation, deposition, or coordination synthesis—to help readers quickly locate suitable options by application scenario.


It is recommended to first review the categories to clarify the intended use (e.g., homogeneous Pt(0) solutions for hydrosilylation, heterogeneous supported Pt catalysts/metal powders, electrocatalyst materials, Pt salts and solution-type Pt sources), then screen by key specifications (such as Pt content/loading (wt%), concentration (mol/L), particle size/dispersion, grade and purity (metals basis), and the solvent/carrier system), and finally use the Aladdin catalog number and CAS number for lookup and cross-referencing.


Please note that the same system may correspond to different CAS numbers depending on its form (e.g., solution, hydrate, or hexahydrate). For solution-type products, it is recommended to consider both the active component and the solvent/carrier information to ensure accurate dosing, compatibility, and reproducibility. For more specifications, please refer to the consolidated product list at the end of the article or search the Aladdin website by CAS number or product name.

Category

Aladdin Cat. No.

Product name

CAS No.

Specification or purity

Key features or applications

Heterogeneous: supported/doped Pt (ready to use)

P475380

Platinum on silica

extent of labeling: 1 wt% loading, dry

Pt supported on SiO (1 wt%); easy filtration and recovery; suitable for heterogeneous screening/pre-scale evaluation

Heterogeneous: supported/doped Pt (ready to use)

G489426

Pt-doped graphene powder

7782-42-5

Pt content: 40–50 wt%

Conductive composite material; preferred for electrocatalysis research; high Pt content for benchmarking and materials development

Heterogeneous: metallic Pt (Pt black/powder) (ready to use)

P433437

Platinum black

7440-06-4

≥99.9% metals basis, fuel-cell grade

Preferred for electrocatalysis/fuel-cell work; low impurities and batch consistency are critical

Heterogeneous: metallic Pt (Pt black/powder) (ready to use)

P1375790

Platinum black

7440-06-4

≥99.99% trace metals basis, ≤100 nm

Nano Pt black; high activity; suitable for rapid screening/electrocatalysis research

Heterogeneous: metallic Pt (Pt black/powder) (ready to use)

P433435

Platinum black

7440-06-4

≥99.9% metals basis, low bulk density

Low bulk density for easier dispersion/coating; more friendly for heterogeneous catalysis and electrocatalyst ink preparation

Heterogeneous: metallic Pt (powder) (ready to use)

P434843

Platinum

7440-06-4

Nano powder, <50 nm particle size (TEM)

Nano Pt powder; suitable for catalysis/conductive fillers/materials research

Heterogeneous: shaped catalyst (specific use)

P141457

Platinum catalyst

For elemental analysis, Pt 5%, Φ: 2–3 mm

Promotes combustion/oxidation for elemental analysis; shaped pellets for easy packing; CAS not provided

Hydrosilylation Pt(0) (silicone rubber curing)

K110178

Platinum(0)-1,3-divinyl-1,1,3,3-tetramethyldisiloxane

68478-92-2

Pt: ~2% in xylene

Classic Pt system for hydrosilylation; dosage can be accurately calculated based on Pt content

Hydrosilylation Pt(0) (silicone rubber curing)

P347686

Platinum(0)-2,4,6,8-tetramethyl-2,4,6,8-tetravinylcyclotetrasiloxane complex solution

68585-32-0

0.104 M in methylvinylcyclosiloxanes

Solution-type Pt(0) for hydrosilylation; convenient formulation and suitable for process screening

Hydrosilylation Pt(0) (more stability-oriented ligands)

B196250

[1,3-Dicyclohexyl-imidazol-2-yl][1,3-divinyl-1,1,3,3-tetramethyldisiloxane]platinum(0)

400758-55-6

≥99.95% metals basis

NHC-ligated system; often better for storage stability/controllability (relative)

Hydrosilylation Pt(0) (more stability-oriented ligands)

B196251

[1,3-Bis(2,6-diisopropylphenyl)imidazol-2-yl][1,3-divinyl-1,1,3,3-tetramethyldisiloxane]platinum(0)

873311-51-4

≥99.95%

NHC-ligated system; one option for improved stability; suitable where a wider formulation window is needed (relative)

Hydrosilylation Pt(0) (more stability-oriented ligands)

B196254

[1,3-Di(2,6-diisopropylphenyl)-2-dihydroimidazolyl][1,3-divinyl-1,1,3,3-tetramethyldisiloxane]platinum(0)

849830-54-2

≥99.95% metals basis

NHC-ligated system; for addition curing/hydrosilylation studies or process screening (relatively more storage-tolerant)

Pt sources: chloroplatinic acid/chloroplatinates (prep/deposition)

H135562

Chloroplatinic acid hydrate

16941-12-1

PrimorTrace™, ≥99.995% metals basis

Ultra-high purity with trace-metal control; preferred for mechanistic/high-sensitivity systems

Pt sources: chloroplatinic acid/chloroplatinates (prep/deposition)

H164499

Chloroplatinic acid, hydrate

26023-84-7

≥99.95% metals basis

Classic Pt source for impregnation/supported catalyst preparation; broadly applicable

Pt sources: chloroplatinic acid/chloroplatinates (prep/deposition)

C755674

Chloroplatinic acid hexahydrate

18497-13-7

BioReagent

Common in bio/coupling-related research; also usable as a Pt source

Pt sources: chloroplatinic acid/chloroplatinates (prep/deposition)

A305395

Ammonium chloroplatinate

16919-58-7

Pt ≥43.4%

Common Pt source; convenient for solution preparation/impregnation

Pt sources: chloroplatinic acid/chloroplatinates (prep/deposition)

A109264

Ammonium chloroplatinite

13820-41-2

Pt 52.0%

Pt(II) salt source; for complex synthesis or supported catalyst preparation

Pt sources: chloroplatinic acid/chloroplatinates (prep/deposition)

P123846

Potassium chloroplatinate

16921-30-5

≥99.9% metals basis

Common Pt source; for solution preparation/impregnation

Pt sources: chloroplatinic acid/chloroplatinates (prep/deposition)

P128374

Potassium chloroplatinite

10025-99-7

≥99.9% metals basis, Pt ≥46%

Pt(II) salt source; suitable for coordination chemistry and catalyst-precursor preparation

Pt sources: chloroplatinic acid/chloroplatinates (prep/deposition)

S100482

Sodium tetrachloroplatinate(II) hydrate

207683-21-4

Pt 44.5%

Pt(II) chloro-complex salt; commonly used Pt source/precursor

Pt sources: chloroplatinic acid/chloroplatinates (prep/deposition)

S109436

Sodium hexachloroplatinate(IV) hexahydrate

19583-77-8

Pt 34.0%

Pt(IV) chloro-complex salt; common for impregnation/deposition

Pt sources: chloroplatinic acid/chloroplatinates (prep/deposition)

S299614

Sodium hexachloroplatinate

16923-58-3

≥98%

General Pt source; commonly used for solution prep/impregnation

Pt sources: simple Pt chlorides (prep/synthesis)

P111013

Platinum(IV) chloride

13454-96-1

Pt ≥57%

Pt salt precursor; can be used to synthesize various Pt complexes/catalyst precursors

Pt sources: simple Pt chlorides (prep/synthesis)

P109265

Platinum(II) chloride

10025-65-7

Pt basis ≥73%

Common Pt(II) salt; for coordination chemistry/catalyst-precursor synthesis

Pt sources: simple chloro complexes (prep/synthesis)

C475102

cis-Diamminetetrachloroplatinum(IV)

16893-05-3

≥99.9% metals basis

Pt(IV) chloro complex; precursor, mechanistic and synthetic starting material

Pt sources: simple chloro complexes (prep/synthesis)

P137460

Potassium trichloroammineplatinate(II)

13820-91-2

≥99.9% metals basis

Pt(II) complex salt; for further ligand substitution/synthesis

Pt sources: simple chloro complexes (prep/synthesis)

P283197

Potassium trichloro(ethylene)platinate(II) monohydrate

12012-50-9

≥98%

Pt(II) complex salt; precursor for synthesis/research

Pt sources: simple chloro complexes (prep/synthesis)

P337335

Potassium trichloro(ethylene)platinate(II) hydrate

123334-22-5

≥95%

Pt(II) complex salt; precursor for synthesis/research

Inorganic precursors: oxides

P141419

Platinum oxide

1314-15-4

Pt, 80–86%

Platinum oxide; can be used directly for some reactions or reduced to active Pt

Inorganic precursors: oxides

P121342

Platinum(IV) oxide monohydrate

12137-21-2

Pt ≥75%

Pt(IV) oxide monohydrate; often used as a reducible precursor

Inorganic precursors: oxides

P109231

Platinum oxide hydrate

52785-06-5

≥99.95% metals basis

High-purity Pt oxide hydrate; more suitable for mechanistic/material preparations

Inorganic precursors: iodides

P304634

Platinum(IV) iodide

7790-46-7

Pt content: 27%

Pt halide precursor; for coordination chemistry/catalyst-precursor synthesis

Inorganic precursors: iodides

P283524

Platinum(II) iodide

7790-39-8

≥98%

Pt(II) halide; catalyst precursor/complex synthesis

Inorganic precursors: bromides

P283169

Platinum(II) bromide

13455-12-4

≥98%

Pt(II) halide; coordination chemistry/catalyst precursor

Inorganic precursors: bromides

P345172

Platinum(IV) bromide

68938-92-1

Pt(IV) halide; precursor/synthetic starting material

Inorganic precursors: sulfides

B299615

Platinum(IV) sulfide

12038-21-0

≥99.9% metals basis

For sulfide systems/electrocatalysis benchmarking; relevant to specific environments

Inorganic precursors: nitrate/sulfite solutions

P100500

Platinum nitrate solution

18496-40-7

Pt, 18.02%

Solution-type Pt source; convenient for quantitative impregnation/preparation

Inorganic precursors: nitrate/sulfite solutions

P283192

Platinum sulfite solution

61420-92-6

15.3% Pt

Solution-type Pt source; suitable for aqueous/impregnation routes

Inorganic precursors: nitrate complexes

T475206

Tetraammineplatinum(II) nitrate

20634-12-2

≥99.995% metals basis

High-purity inorganic Pt precursor; suitable for synthesis/deposition/mechanistic studies

Inorganic precursors: hexa-halo platinates

S358530

Sodium hexabromoplatinate(IV) hexahydrate

39277-13-9

Pt 23.5%

Pt(IV) hexa-halo complex; for complex synthesis/precursors

Inorganic precursors: hexa-halo platinates

P283194

Potassium hexabromoplatinate(IV)

16920-93-7

≥99%

Pt(IV) hexa-halo salt; precursor/synthetic starting material

Inorganic precursors: hexa-halo platinates

P475076

Potassium hexaiodoplatinate(IV)

16905-14-9

≥99.7% metals basis

Pt(IV) hexa-halo salt; precursor/synthetic starting material

Inorganic precursors: hexahydroxyplatinate (salts/acids)

S407343

Sodium hexahydroxyplatinate(IV)

12325-31-4

51.2–62.5% Pt basis (gravimetric)

Water-soluble/alkaline Pt(IV) source; friendly for aqueous preparation/deposition

Inorganic precursors: hexahydroxyplatinate (salts/acids)

P580689

Potassium hexahydroxyplatinate(IV)

12285-90-4

≥99.95% metals basis

High-purity hexahydroxyplatinate; more convenient in aqueous systems

Inorganic precursors: hexahydroxyplatinate (salts/acids)

H475078

Hexahydroxyplatinic acid(IV)

51850-20-5

≥99% metals basis

Acid form; more flexible for formulation/system selection

Inorganic precursors: other solution-type Pt sources

D407365

Dihydrogen dinitrosyl sulfate platinum(II) solution, Pt 4–6% (cont. Pt)

12033-81-7

Solution-type Pt source; convenient dosing and content control

Solutions/colloids: dispersed Pt

P283147

Pt/tetra-n-octylammonium chloride colloid

7440-06-4

purified 70–85% Pt

Colloidal dispersed Pt; easy to introduce into organic phases/material systems; suitable for composite catalyst materials

Solutions/colloids: dispersed Pt

P294944

Platinum (TAA) solution

127733-97-5

≥99.95% metals basis

Solution-type Pt; convenient for metering and homogeneous introduction

Homogeneous: COD / labile-ligand Pt(II)

D295020

(1,5-Cyclooctadiene)platinum(II) dichloride

12080-32-9

≥99.95% metals basis

Common Pt(II) precursor; ligands readily exchanged; suitable for homogeneous catalysis/complex synthesis

Homogeneous: COD / labile-ligand Pt(II)

D130073

(1,5-Cyclooctadiene)platinum(II) dibromide

12145-48-1

≥98%

Similar to COD dichloride; halide difference for route selection/comparison

Homogeneous: COD / labile-ligand Pt(II)

C124086

(1,5-Cyclooctadiene)platinum(II) dimethyl

12266-92-1

≥97%

Pt(II) organometallic precursor; for synthesis/mechanistic studies

Homogeneous: labile-ligand Pt(II)

D468633

Dichloro(norbornadiene)platinum(II)

12152-26-0

≥97%

NBD-type complex; suitable for further ligand exchange/homogeneous catalysis research

Homogeneous: labile-ligand Pt(II)

D468624

Dichloro(dicyclopentadienyl)platinum(II)

12083-92-0

≥97%

Ligand-exchangeable Pt(II) precursor; for synthesis and catalysis research

Homogeneous: dba-type Pt(0) precursor

T283160

Tris(dibenzylideneacetone)platinum(0)

11072-92-7

≥98%

Active Pt(0) precursor; commonly used for homogeneous screening/ligand-system development

Homogeneous: dba-type Pt(0) precursor

T283161

Tris(dibenzylideneacetone)dipltinum(0)

63782-74-1

≥98%

Pt(0) precursor; used to generate active Pt(0) species for catalyst screening

Homogeneous: Cp/organometallic Pt precursor

T283162

(Trimethyl)ethylcyclopentadienylplatinum(IV)

229621-40-3

≥99.999%

Organometallic Pt precursor; for synthesis/deposition/mechanistic studies

Homogeneous: Cp/organometallic Pt precursor

T283159

(Trimethyl)pentamethylcyclopentadienylplatinum(IV)

97262-98-1

≥99%

Organometallic Pt precursor; for complex synthesis and catalysis research

Homogeneous: dedicated catalyst

H283157

Hydrido(dimethylphosphinate-kP)[bis(hydrido(dimethylphosphinate-kP))]platinum(II) [Ghaffar–Parkins catalyst]

173416-05-2

≥95%

Classic research catalyst; for specific reactions/mechanistic benchmarking

Homogeneous: β-diketone Pt(II)

P119026

Platinum(II) acetylacetonate

15170-57-7

PrimorTrace™, ≥99.99% metals basis

Good solubility; commonly used in homogeneous catalysis/material deposition/precursors (high purity)

Homogeneous: β-diketone Pt(II)

P283174

Platinum(II) hexafluoroacetylacetonate

65353-51-7

≥99.9% metals basis

Stronger electron-withdrawing ligand system; common in deposition/precursor and comparison studies

Homogeneous: carbonyl Pt(II)

C283155

cis-Dichlorodicarbonylplatinum(II)

25478-60-8

≥99.9% metals basis

Carbonyl complex; for mechanistic studies/coordination-chemistry feedstock

Homogeneous: oxalate Pt complex salts

P475072

Potassium bis(oxalato)platinate(II) dihydrate

14244-64-5

≥99.9% metals basis

Water-soluble Pt complex salt; for complex synthesis/deposition research

Homogeneous: oxalate Pt complex salts

P283193

Potassium oxalatoplatinate(II) dihydrate

38685-12-0

≥99%

Same category as above; for comparison/route selection

Homogeneous: phosphine-ligated Pt (common)

B488697

Bis(tri-tert-butylphosphine)platinum(0)

60648-70-6

≥95%

Pt(0) phosphine system; for homogeneous catalysis/ligand-effect research

Homogeneous: phosphine-ligated Pt (common)

T107487

Tetrakis(triphenylphosphine)platinum

14221-02-4

Pt 15.2%

Classic phosphine-ligated Pt; homogeneous catalysis/synthetic precursor

Homogeneous: phosphine-ligated Pt (common)

C129176

cis-Dichlorobis(triphenylphosphine)platinum

15604-36-1

Pt ≥24.2%

Classic starting material; convenient for ligand exchange/homogeneous benchmarking

Homogeneous: phosphine-ligated Pt (common)

I167193

trans-Dichlorobis(triphenylphosphine)platinum(II)

14056-88-3

≥98%

trans isomer for comparison; ligand/configuration effect studies

Homogeneous: phosphine-ligated Pt (common)

T299651

Dichlorobis(tributylphosphine)platinum

15076-72-9

≥98%

Alkyl-phosphine system; used to compare solubility/steric effects

Homogeneous: phosphine-ligated Pt (common)

C129173

cis-Dichlorobis(triethylphosphine)platinum(II)

15692-07-6

≥98%

Small alkyl-phosphine system; electronic/steric comparisons

Homogeneous: phosphine-ligated Pt (common)

B299617

1,4-Bis(diphenylphosphino)butane dichloroplatinum

65097-96-3

≥95%

Chelating bisphosphine system; facilitates specific coordination environments

Homogeneous: aromatic nitrile-ligated Pt(II)

B113726

Bis(benzonitrile)dichloroplatinum(II)

14873-63-3

Pt ≥41.0%

Nitrile ligands readily exchanged; common for homogeneous precursors/ligand exchange

Homogeneous: nitrile-ligated Pt(II)

B302790

cis-Bis(acetonitrile)dichloroplatinum(II)

13869-38-0

≥98%

Reactive precursor; acetonitrile is labile for introducing target ligands

Homogeneous: DMSO-ligated Pt(II)

C468971

cis-Dichlorobis(dimethyl sulfoxide)platinum(II)

22840-91-1

≥97%

DMSO complex; common in synthesis/mechanistic/solubility studies

Homogeneous: pyridine-ligated Pt(II)

C283523

cis-Dichlorobis(pyridine)platinum(II)

15227-42-6

≥99%

Classic pyridine complex; homogeneous research/precursor

Homogeneous: pyridine-ligated Pt(II)

C129172

cis-Dichlorobis(pyridyl)platinum(II)

14872-21-0

≥99%

Pyridine-type comparison; ligand electronic-effect studies

Homogeneous: thioether-ligated Pt(II)

C130098

cis-Dichlorobis(diethyl sulfide)platinum(II)

15442-57-6

≥98%

Thioether ligand system; coordination stability/reactivity comparisons

 

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Categories: Technical articles
Explore topics: Platinum Catalysts

Da — when not otherwise indicated, molecular weight units are daltons.   Mw — weight-average molecular weight.   Mn — number-average molecular weight.

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Cite this article

Aladdin Scientific. "How to Select and Use Platinum Catalysts: A Complete Guide to Homogeneous, Heterogeneous, and Electrocatalysis (with an Aladdin Catalog No. Cross-Reference Table)" Aladdin Knowledge Base, updated 24 dic 2025. https://www.aladdinsci.com/us_es/faqs/how-to-select-and-use-platinum-catalysts-en.html
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