Technical articles

Making Sense of Rhodium Catalysis: Three Core Engines—Rh(I), Rh(II), and Cp*Rh(III)—plus a Quick Selection Guide to Representative Product Tables A–G

You often see the words “Rh catalysis” in the literature, but in the lab it usually refers to a whole variable system: the rhodium input form (salt/oxide/supported material/complex), counteranions and ligands, solvent, and additives together determine what the true active species is in the reaction. That, in turn, explains why activity and selectivity can “jump” when you change what looks like a minor detail.

This article uses a practical framework—Rh source → precatalyst → active species—to make rhodium catalysis intuitive and actionable. The companion Tables A–G at the end help you start from the task and quickly locate: which “engine” to choose, which table to begin with, and which variables are most likely to cause run-to-run drift.

What does “rhodium catalyst” actually mean?

Why can the same element (Rh) behave so differently when you change the precursor/anion/ligand? Start by separating three concepts:

  1. Rhodium source (Rh source): the starting material that supplies rhodium, such as RhCl₃·xHO, rhodium nitrate, Rh(acac), RhO, rhodium black, Rh/C, Rh/AlO, etc. These are not necessarily the real active species in the reaction, but they constrain which activation pathways are accessible later.
  2. Precatalyst: a well-defined, weighable, storable convertible form that becomes the active species under the reaction conditions. Examples include [RhCl(COD)], [Rh(COD)]BF, [Cp*RhCl], Rh(OAc), and so on.
  3. Active species: the transient species that actually performs key steps during catalysis (e.g., H activation, insertion, reductive elimination, carbene transfer, CH metalation). In solution it may exist as a dynamic equilibrium of multiple forms, strongly influenced by ligands, anions, solvent, and trace impurities.

Note: These are functional roles, not strict chemical categories; the same reagent can play different roles in different systems.

Why rhodium is often seen as “expensive but worth it”: four classic strengths

Rhodium catalysis is repeatedly used in organic synthesis and in materials/process chemistry mainly because it excels at four things:

  1. High selectivity and mild conditions in homogeneous hydrogenation/addition: Rh systems exemplified by Wilkinson’s catalyst are milestones in the history of homogeneous hydrogenation. Early work already demonstrated pathways where Rh complexes participate in hydrogenation via metal–hydride intermediates.
  2. Industrial impact of asymmetric hydrogenation: Work exemplified by Knowles established chiral Rh-catalyzed asymmetric hydrogenation as a major pillar of modern enantioselective synthesis.
  3. Two modern “engines”: Rh(II) carbene transfer + Rh(III) C–H activation: Dirhodium “paddlewheel” catalysts are highly efficient and classic in carbene chemistry, while Cp*Rh(III) occupies a central position in directed C–H functionalization.
  4. Hydroformylation/carbonylation (syngas: CO/H) as an industrial backbone: Under CO/H, Rh(I) readily enters working states such as Rh–H / Rh–CO, enabling olefin hydroformylation (to aldehydes) and related carbonylation reactions under relatively mild conditions. Importantly, linear/branched selectivity (n/iso), rate, and side reactions can often be engineered by tuning phosphine/phosphite ligand electronics and sterics and by adjusting CO partial pressure—making this a mature large-scale Rh platform.

The three most common “rhodium active centers”: Rh(I) / Rh(II) / Rh(III)

Engine (common oxidation state)

“Tags” you often see in product names

Typical precatalysts/precursors (examples)

Common activation modes

Signature reactions / capability boundaries

Selection tips

Rh(I) (the main homogeneous workhorse; often enters Rh(I)/Rh(III) cycles)

COD, NBD, MeCN, PPh; also BF₄⁻/PF₆⁻/OTf/SbF₆⁻/BArF₄⁻ (often in cationic systems)

Chloride-bridged dimers such as [RhCl(COD)]; cationic [Rh(diene)]X; classic platforms such as RhCl(PPh)

Ligand exchange / creation of coordination vacancies; cationic systems are more strongly affected by ion pairing, anion weak-coordination, and solubility

Hydrogenation, additions, isomerization, (some) carbonyl-related platforms; asymmetric hydrogenation often uses chiral bisphosphine–Rh(I)

For rapid screening: start from general Rh(I) precursors and build a ligand library (Table B). For ee: go directly to pre-formed chiral Rh(I) catalysts (Table C).

Rh(II) dirhodium (paddlewheel)

“Dirhodium(II)”, “Rh₂(OOCR)₄”, paddlewheel; various carboxylate/ chiral ligand names

Rh(OAc), Rh(TFA), chiral Rh(DOSP), BTPCP, PTAD, etc.

Reaction with carbene precursors to form metal–carbene; axial sites/additives/solvent may also modulate

Cyclopropanation, C–H insertion, X–H insertion (carbene transfer); chiral dirhodium controls enantioselectivity

First make it work: achiral dirhodium (Table D). For ee: chiral dirhodium (Table E).

Rh(III) (especially Cp*Rh(III))

CpRh, [CpRhCl]; often described together with “silver salt / halide abstraction” conditions

[Cp*RhCl]; halide-free or weakly coordinating anion CpRh(III) precursors

Commonly: halide abstraction → more reactive Rh(III) (silver salts are common, but silver-free routes exist)

Directed C–H activation/cyclization/coupling; sensitive to additive package and substrate directing groups

For C–H activation, start with Table F. If you need “cleaner activation,” compare with halide-free/weakly coordinating precursors.

Homogeneous vs heterogeneous: selection is not only about separation, but also “site controllability + process pathway”

Dimension

Homogeneous Rh catalysis

Heterogeneous/supported Rh catalysis (Rh/C, Rh/AlO, rhodium black, etc.)

Practical, actionable tip

What is the active site?

Molecular, often structurally definable Rh complexes/intermediates; sites are more “describable”

Surface atoms/edges/defects/metal–support interfaces; sites may change dynamically; identification and counting are harder

For mechanistic clarity and predictable optimization: homogeneous is usually easier; heterogeneous relies more on experience plus characterization/controls

What can be tuned (selectivity tools)?

Fine control via ligand electronics/sterics/chirality—especially good for ee and site selectivity

Mainly via support, dispersion, particle size, metal–support interactions, additives, and conditions; fewer “chiral tools” (unless special strategies)

If you need ee/high stereoselectivity → prioritize homogeneous

Activity/selectivity (typical trend)

Often easier to reach both high activity and high selectivity; more predictable

Selectivity may be influenced by support and mass transfer; modern heterogeneous systems can also be very strong (not inherently worse)

Separation/recycling/continuous operation

Separation is often harder; recycling may require extraction, immobilization, biphasic systems, membranes, etc.

Filtration/fixed beds are natural; often better for scale-up and continuous production

If the goal is scale-up, recycling, continuous processing: heterogeneous often has an edge

Sensitivity to impurities/handling

Often more sensitive to water/oxygen/halides/strongly coordinating impurities; reproducibility depends on operational discipline

Also sensitive to some impurities, but problems often stem from mass transfer, bed/stirring, deactivation (sintering/poisoning)

For homogeneous: lock down “cleanliness/order/ligands.” For heterogeneous: lock down “stirring/H pressure/filtration/reuse.

Key reminders

Control metal residues; workup losses; active species may not match the input structure (confirm by controls)

Leaching/redeposition can make a system “look heterogeneous” while homogeneous species participates; sites are hard to define

Do a “hot filtration test” (does it keep reacting after filtration?) and measure metal residues (e.g., ICP)

From precatalyst → active species: common activation pathways in Rh catalysis

Activation pathway

Common precursors / “name clues”

What typically happens

Most sensitive variables (often cause “jumps”)

A. Ligand dissociation / dimer cleavage → coordination vacancy

Rh(I)–COD/NBD/MeCN/PPh; chloride-bridged dimers such as [Rh(μ-Cl)(COD)]; cationic [Rh(COD)]BF

“Occupying ligands stabilize first, then vacate under reaction conditions”; dimers are split into mononuclear species that can enter the catalytic cycle

Ligand addition order and equivalents; solvent donor strength; presence of halides/strongly coordinating impurities

B. Halide abstraction/activation (common in Rh(III) C–H)

[Cp*RhCl] + AgX / AgOAc etc.

“Remove Cl⁻ to make Rh more open and reactive, facilitating species that can undergo CH metalation (note: Ag salts can do more than just halide abstraction)

Ag salt identity and loading; anion (SbF₆⁻/BF₄⁻/OTf, etc.); presence of acetate/base (affects CMD)

C. Formation of key intermediates (Rh–H / Rh–carbene / Rh–metalated)

Hydrogenation: Rh(I) precursors; carbene: Rh(OOCR); C–H: Cp*Rh(III)

Hydrogenation: Rh(I) oxidative addition → Rh(III) dihydride, then insertion and reductive elimination; carbene: Rh–carbene generation and transfer (often from diazo compounds); C–H: Rh–C bond formation (CMD, etc.)

Dryness/inert atmosphere; additives (base/acid/halide scavengers); substrate coordination interference

D. Redox / reductive activation (often overlooked but critical)

Rh(III) salts or higher-oxidation precursors; in some cases metal Rh(0)/nanoparticles form

First “reduce into a catalytically competent state” (Rh(I) or Rh–H); reductants may come from H, phosphines, substrate, or additives

Whether a reductant exists; induction period; impurities (O/HO/halides)

Reading product names: quickly tell “which engine it is” and “what it’s for”

When you see in the name…

Usually which “engine/family”

Go to which table first

Use-case hint

COD / NBD / MeCN / PPh (especially with Rh(I))

Mostly Rh(I) homogeneous precursors/platforms

Table B (general Rh(I)) / Table C (chiral Rh(I))

“Stabilize first, then activate/ligand exchange”; good for library screening and literature benchmarking

Rh( ) / dirhodium(II) / paddlewheel

Rh(II) dirhodium (carbene transfer)

Table D (achiral) / Table E (chiral)

Cyclopropanation, C–H/X–H insertion; for ee, go straight to chiral dirhodium

CpRh / [CpRhCl]

Typical Rh(III) C–H activation platform

Table F

Directed C–H activation/cyclization/coupling; often paired with halide abstraction/activation additives

Rh/C, Rh/AlO, rhodium black, Rh powder

Heterogeneous/material-side Rh

Table A

Easier separation/recycling and scale-up; watch mass transfer, support/dispersion, and reproducibility

The three most common “sensitivity points” in Rh catalysis

Sensitivity point

What it usually causes

Common symptoms

Quick response

Trace water/oxygen

Affects activation, changes oxidation state/intermediate equilibria → induction periods and reproducibility drift

“Sometimes fast, sometimes dead” under nominally identical conditions; large day-to-day differences with the same catalyst batch

Dry solvents/glassware; inert atmosphere; standardize addition order and pre-activation time

Halides/strongly coordinating impurities (Cl/Br; strongly coordinating S/N compounds, etc.)

Can passivate cationic Rh(I) or alter Rh(III) activation pathways

Reaction “suppressed,” clear activity drop; suddenly improves after adding Ag salt or switching anion

Control halide sources; run halide scavenging/abstraction controls when needed; avoid strongly coordinating impurities

Ion pairing & solubility (anion effects)

Changes how “naked” a cationic Rh(I) is, ion-pair tightness, and solubility → rate/selectivity shifts

Results “jump” when switching BF₄⁻/OTf/SbF₆⁻/BArF₄⁻

Treat the anion as a tunable knob; run a small matrix (anion × solvent × ligand) and record solubility/turbidity

Notes:

  1. 5For heterogeneous systems, additionally watch mass transfer/stirring/H pressure and catalyst wetting/dispersion; otherwise what looks like a catalyst issue is often a mass-transfer issue.
  2. Strongly coordinating sulfur/amine species and the site-blocking effect of CO: many Rh(I) systems are easily “captured” and passivated by such ligands—especially when using more “naked” cationic Rh(I). This often looks like catalyst failure, but is actually coordination inhibition.

Aladdin Rhodium Catalyst R&D Selection & Application Navigation: Representative Product Subtables (Tables A–G; Rh sources / homogeneous Rh(I) / chiral Rh(I) / Rh(II) / Cp*Rh(III) / clusters)

Navigation for Rhodium Catalyst Product Tables

Your goal/task

Start with which table

What this table mainly contains

Typical use scenarios

Quick in-table screening keywords

Need a metal Rh source/salt/solution, or want to make supported catalysts/electroplating/material precursors

Table A

Rh(III) inorganic salts/solutions, Rh oxides, supported Rh/C, etc.

Preparing supported Rh catalysts (impregnation → reduction), making Rh solutions, materials/electrochemistry/surface treatment, process-scale “feedstock side”

“rhodium nitrate / rhodium chloride / rhodium bromide / rhodium sulfate solution / rhodium oxide / Rh on carbon”

Want to quickly build a general homogeneous Rh(I) system and screen ligands yourself

Table B (precursor section)

Rh(I) precursors with exchangeable ligands (COD/NBD/olefin/acac/MeCN, etc.), cationic [Rh(diene)]

Homogeneous hydrogenation/isomerization/addition/coupling: precursor + candidate ligand library for fast condition scouting

“(COD)₂Rh, NBD, acac, MeCN, chloride-bridged dimer, BF4/OTf/PF6/SbF6/BArF4

Don’t want to formulate ligands yourself; want plug-and-play Rh(I) platforms for quick validation/benchmarking

Table B (mature platforms section)

Pre-ligated platforms with PPh/CO/H etc. (Wilkinson-type, RhH, RhCO, etc.)

Literature benchmarking, teaching demos, quick “can this route run?”, mechanistic controls (Rh–H/Rh–CO)

“PPh₃, Wilkinson, hydride, carbonyl, RhCO, RhH

Need asymmetric hydrogenation/asymmetric addition with ready-made chiral Rh(I) catalysts

Table C

Pre-formed chiral Rh(I) catalysts based on commercial chiral ligands (DUPHOS, BPE, NORPHOS, BINAP, phane, ferrocene, etc.)

ee is the goal: start from mature chiral families, then fine-tune ligand family, anion (BF4/OTf, etc.), solvent, additives

“DUPHOS, BPE, NORPHOS, BINAP, phane, ferrocene, catASium, BF4/OTf”

Doing carbene transfer (cyclopropanation, C–H insertion, X–H insertion) without emphasizing chirality

Table D

Achiral Rh(II) dirhodium with varied carboxylate/ligand environments (OAc, TFA, perfluorocarboxylates, bulky carboxylates, lactamates, etc.)

First make the reaction work; tune activity/selectivity/solubility by changing carboxylate environment

“Rh2, dirhodium, acetate/TFA/pivalate/perfluoro, caprolactamate”

Doing enantioselective carbene transfer (ee-focused cyclopropanation/insertion)

Table E

Chiral Rh(II) dirhodium (DOSP, BTPCP, PTAD, amino-acid-derived families, etc.)

ee is the core metric: start from mature chiral dirhodium families, then match substrates and fine-tune conditions

“Rh2(DOSP), BTPCP, PTAD, Leu/Phe-derived, HPLC grade”

Doing C–H activation / directed cyclization / coupling (Cp*Rh(III) systems) or cyclometalated Rh(III) chemistry

Table F

CpRh(III)Cl dimer, halide-free cationic CpRh(III), cyclometalated Rh(III) dimers, etc.

Reproducing Cp*Rh(III) literature systems; comparing “cleaner activation” using halide-free/weakly coordinating anion precursors

“Cp*Rh, pentamethylcyclopentadienyl, SbF6, cyclometalated (2-phenylpyridine)”

Doing mechanistic/clusters/CO chemistry, or want cluster precursors

Table G

Rh carbonyl clusters, hydride clusters, etc. (more mechanism/model oriented)

Mechanistic models, cluster/nanoparticle precursor exploration, CO coordination and cluster chemistry

“Rh4(CO)12, Rh6(CO)16, μ-hydride cluster”

Table A | Engineering/Materials-Facing Rh Sources (Rh(III) Salts/Solutions/Oxides + Supported Catalysts)

Category

Aladdin Cat. No.

Product name

CAS No.

Spec./Purity

Key features / typical uses

Rh(III) nitrate (hydrated) precursor

R431254

Rhodium(III) nitrate hydrate

10139-58-9

~36% Rh

Aqueous Rh(III) metal source; commonly used to prepare Rh salt solutions, synthesize complexes, or impregnate supports to make supported Rh catalysts

Rh(III) nitrate (assay specified)

T1373807

Same as above (adduct; N content specified)

154090-43-4

Elemental analysis: N 3.30–4.50%

Suitable when “batch-consistent / assay-specified” charging is required for controlled dosing and comparative studies

Supported Rh/C (heterogeneous)

R485647

Rhodium on activated carbon

Water-wet; 5% Rh (on dry basis)

Classic heterogeneous hydrogenation/reduction catalyst; water-wet form improves handling safety and weighing/transfer

Supported Rh/C (heterogeneous, with stabilizer)

R111023

Rhodium on carbon catalyst

7440-16-6

5% Rh; contains 55–60% water stabilizer

Widely used for heterogeneous hydrogenation/reduction; water stabilizer improves storage/handling safety and is helpful for scale-up evaluation

Metallic Rh (powder/black) for heterogeneous catalysis/materials

R109241

Rhodium black

7440-16-6

≥99.9% metals basis

High-surface-area metallic Rh; often used for heterogeneous hydrogenation/reduction, materials/electrochemical benchmarks, and as a metal source for preparing supported Rh

Supported Rh/AlO (heterogeneous)

R383782

Rhodium on alumina

7440-16-6

5 wt.% loading labeling, matrix alumina support

Classic supported catalyst (Rh/AlO) for hydrogenation/hydrogenation under gas-phase or scale-up conditions; support affects dispersion and selectivity (useful comparison to Rh/C)

Rh(III) chloride (hydrated) precursor

R109233

Rhodium(III) chloride hydrate

20765-98-4

Rh 38.5–42.5%

Classic Rh(III) metal source for Rh complex synthesis, catalyst precursors, and supported Rh preparation

Rh(III) chloride (trihydrate) precursor

R190691

Rhodium(III) chloride trihydrate

13569-65-8

≥98%

RhCl₃·xHO-type precursor; suitable for routine Rh complex synthesis and catalyst system setup

Rh(III) chloride (anhydrous/low-water) precursor

R132432

Rhodium chloride

10049-07-7

≥98%

RhCl-type metal source; more compatible with moisture-sensitive systems; often used for complex synthesis and for making Rh by supported/reductive routes

Rh(III) bromide (hydrated) precursor

R665349

Rhodium(III) bromide hydrate

123333-87-9

Rh 23.6%

Rh(III) halide source; useful for halide-effect controls or specific Rh(III) complex synthesis

Rh(III) bromide (dihydrate) precursor

R282830

Rhodium(III) bromide dihydrate

15608-29-4

≥97%

Rh(III) bromide source; commonly used for Rh complex/precatalyst preparation and condition benchmarking

Rh(III) iodide precursor

R117876

Rhodium(III) iodide

15492-38-3

Rh 21.3%

Rh(III) iodide metal source; suitable for halide exchange and coordination-strength comparison studies

Rh oxide / materials precursor

R322316

Rhodium(III) oxide pentahydrate

39373-27-8

≥99.95% metals basis

High-purity hydrated Rh(III) oxide precursor; used for demanding coordination/material precursor work and catalytic controls

Rh(III) nitrate (dihydrate) precursor

R339896

Rhodium(III) nitrate dihydrate

13465-43-5

≥95%

Rh(III) nitrate metal source for solution preparation and impregnation–reduction routes to Rh/C or Rh/oxide supports

Rh(III) sulfate solution precursor

R346721

Rhodium sulfate solution

10489-46-0

≥99.95% metals basis

Aqueous Rh solution metal source; commonly used for electroplating/surface treatment or impregnation-based preparation of supported Rh

Rh(III) carboxylate precursor

H124011

Rhodium(III) acetate

42204-14-8

Rh ≥38%

Rh(III) carboxylate metal source; used for complex synthesis and selected homogeneous catalyst-precursor routes

Rh(III) β-diketonate complex (high purity)

R118540

Rhodium(III) acetylacetonate (Rh(acac))

14284-92-5

PrimorTrace™, ≥99.99% metals basis

High-purity Rh(acac); common in coordination/material precursor studies and catalytic benchmarks

Rh oxide (materials/heterogeneous precursor)

R113303

Anhydrous rhodium oxide

12036-35-0

≥99.8% metals basis, Rh ≥80.6%

Used in materials/electrochemistry/heterogeneous studies; can also serve as a precursor for reduction to Rh or supported Rh preparation

Table B | General Homogeneous Rh(I) (Mostly Achiral): Ligand-Exchangeable Precursors + Mature PPh/CO/H Platforms

Category

Aladdin Cat. No.

Product name

CAS No.

Spec./Purity

Key features / typical uses

Rh(I) chloro-bridged COD dimer precursor

C113573

Chloro(1,5-cyclooctadiene)rhodium(I) dimer

12092-47-6

Rh 41.7%

One of the most commonly used Rh(I) starting materials; readily undergoes ligand exchange / halide abstraction to generate active Rh(I) species (hydrogenation/addition/isomerization, etc.)

Rh(I) chloro-bridged NBD dimer precursor

B293967

Chloro(norbornadiene)rhodium dimer

12257-42-0

≥99.95% metals basis

“Workhorse” precursor similar to COD; NBD is easily displaced—useful for rapid construction of ligated Rh(I) catalysts

Rh(I) chloro-bridged olefin dimer precursor

C118535

(Bicyclooctene)chloro-rhodium dimer

12279-09-3

≥98%

Olefin ligand is exchangeable; used to rapidly generate ligated Rh(I) catalysts and screen conditions

Rh(I) chloro-bridged diene dimer precursor

C118545

Chloro(1,5-hexadiene)rhodium(I) dimer

32965-49-4

≥98%

More “readily activatable” olefin precursor; often used in ligand screening and mechanistic benchmarking

Rh(I) chloro-bridged vinyl dimer precursor

D118537

Chloro-di(vinyl)rhodium(I) dimer

12081-16-2

≥98%

Vinyl/olefin-type precursor; used to build Rh(I) active centers via ligand exchange or for related mechanistic studies

Rh(I) COD–acac neutral precursor

A284018

(1,5-Cyclooctadiene)(2,4-pentanedionato)rhodium(I)

12245-39-5

≥99.95% metals basis

Neutral and soluble; suitable for ligand substitution and building a homogeneous Rh(I) library (screening reaction window/solvent/additives)

Rh(I) NBD–acac neutral precursor

A118525

(Norbornadiene)(acetylacetonato)rhodium

32354-50-0

≥97%

Neutral Rh(I) precursor; commonly used for rapid installation of phosphine/N ligands to build catalytic systems

Rh(I) olefin–acac neutral precursor

A282799

Acetylacetonato bis(cyclooctene)rhodium(I)

34767-55-0

≥97%

Neutral; olefin is readily exchangeable—useful for ligand screening and generating active Rh(I) species

Rh(I) acac–olefin neutral precursor

A118538

Acetylacetonato bis(ethylene)rhodium(I)

12082-47-2

≥95%

Neutral Rh(I) platform; used to construct ligated Rh(I) catalysts and for mechanistic comparisons

Rh(I) COD–(8-quinolinato) chelate

C469098

(1,5-Cyclooctadiene)(8-quinolinolato)rhodium(I)

33409-86-8

≥97%

Neutral N,O-chelated Rh(I); suitable for coordination/activation-pathway studies and as a precursor in specific systems

Rh(I) alkoxy–COD dimer

M138106

Methoxy(1,5-cyclooctadiene)rhodium(I) dimer

12148-72-0

≥98%

Rh–OMe reactive precursor; useful for building Rh(I) systems under halide-free/low-salt conditions or as a base-related control

Rh(I) hydroxy–COD dimer

H467391

Hydroxy(1,5-cyclooctadiene)rhodium(I) dimer

73468-85-6

≥95%

Rh–OH reactive precursor; facilitates generation of ligated Rh(I) active centers; useful for activation/mechanistic controls

Rh(I) cation “stabilized adduct”

C282825

(1,5-Cyclooctadiene)(hydroquinone)rhodium(I) tetrafluoroborate

120967-70-6

≥95%

Stabilized source of cationic Rh(I); safer/more reliable for weighing and storage, releases active Rh(I) in situ

Rh(I) cation [Rh(COD)] (BF₄⁻)

B140876

Bis(1,5-cyclooctadiene)rhodium tetrafluoroborate

35138-22-8

Rh 24.8%

Common cationic precursor; convenient for introducing ligands (including chiral ligands) to build homogeneous catalysts

Rh(I) cation [Rh(COD)] (OTf)

B284034

Bis(1,5-cyclooctadiene)rhodium triflate

99326-34-8

≥99.95% metals basis

Weakly coordinating anion often promotes activation; used to build high-activity Rh(I) systems and for rapid ligand exchange

Rh(I) cation [Rh(NBD)] (BF₄⁻)

B284043

Bis(norbornadiene)rhodium(I) tetrafluoroborate

36620-11-8

≥99.95% metals basis

NBD dissociates/is replaced readily; suitable for fast generation of active Rh(I) centers (hydrogenation/addition, etc.)

Rh(I) cation [Rh(COD)] (hydrated BF₄⁻)

B168465

Bis(1,5-cyclooctadiene)rhodium(I) tetrafluoroborate hydrate

207124-65-0

≥97%

Hydrated form as listed; still a common cationic precursor for ligand introduction and condition screening

Rh(I) cation [Rh(COD)] (PF₆⁻)

B589714

Bis(1,5-cyclooctadiene)rhodium hexafluorophosphate

62793-31-1

≥98%

Common cationic precursor; PF₆⁻ can help with solubility/ion-pairing controlsuseful for achiral and asymmetric library building

Rh(I) MeCN “activated-site” precursor (BF₄⁻)

B169584

Di(acetonitrile)(1,5-cyclooctadiene)rhodium(I) tetrafluoroborate

32679-02-0

≥98%

MeCN is labile → easier activation; suitable for quickly generating ligated Rh(I) active centers

Rh(I) cation [Rh(COD)] (SbF₆⁻)

B468674

Bis(1,5-cyclooctadiene)rhodium(I) hexafluoroantimonate

130296-28-5

≥97%

Extremely weakly coordinating anion; often chosen for highly active cationic Rh(I) systems (“cleaner” activation)

Rh(I) cation [Rh(NBD)] (OTf)

B468858

Bis(norbornadiene)rhodium(I) triflate

178397-71-2

≥97%

OTf is weakly coordinating; helps form more reactive Rh(I) centersgood for ligand exchange/activity benchmarking

Rh(I) MeCN/COD mixed cation (BF₄⁻)

B282800

Bis(acetonitrile)(1,5-cyclooctadiene)rhodium(I) tetrafluoroborate

46360-78-5

≥97%

Combines COD stabilization with MeCN lability; suitable for “quick-start” homogeneous screening

Rh(I) ultra-weakly coordinating anion (BArF₄⁻)

B432697

Bis(1,5-cyclooctadiene)rhodium(I) tetrakis[bis(3,5-trifluoromethyl)phenyl]borate

404573-66-6

BArF₄⁻ is extremely weakly coordinating; used to access highly “naked” cationic Rh(I) for high-activity exploration

Rh(I) PPh platform (Wilkinson-type)

W347495

Rhodium(I) chloride tris(triphenylphosphine) (NSC 124140)

14694-95-2

≥99.95% metals basis

Classic homogeneous hydrogenation platform; well-defined ligation, good reproducibility—useful for teaching/screening/benchmarking

Rh(I) PPh platform (halide variant)

B580700

Rhodium(I) bromide tris(triphenylphosphine)

14973-89-8

≥99.95% metals basis

Same family as the chloride; used for halide-effect/activation comparisons and condition optimization

Rh(I) hydride (PPh)

H597603

Tetrakis(triphenylphosphine)rhodium(I) hydride

18284-36-1

Rh 8.4% min

Common precursor for homogeneous hydrogenation; relates directly to Rh–H active forms—useful for hydrogenation/isomerization, etc.

Rh(I) carbonyl hydride (PPh)

C117877

Carbonylhydridotris(triphenylphosphine)rhodium(I)

17185-29-4

≥97%

Rh–H/CO platform; often used for hydroformylation/carbonylation-related mechanistic and catalytic benchmarking

Rh(I) carbonyl chloride (PPh)

B113668

Chlorocarbonylbis(triphenylphosphine)rhodium(I)

13938-94-8

Rh ≥14.90%

Rh–CO platform; suitable for carbonylation, ligand exchange, and mechanistic controls

Rh(I) carbonyl–β-diketonate–PPh platform

C124012

Carbonylacetylacetonato(triphenylphosphine)rhodium(I)

25470-96-6

Rh 21%

Contains CO/β-diketonate/PPh simultaneously; used for carbonylation-related screening and ligand-exchange routes

Rh(I) dicarbonyl–β-diketonate platform

A293954

Dicarbonyl(acetylacetonato)rhodium

14874-82-9

≥99.95% metals basis

(CO) platform that readily undergoes ligand substitution; useful as a carbonylation/activation precursor and benchmark

Rh(I) carbonyl chloro-bridged dimer

D118541

Di-μ-chloro-tetracarbonyldirhodium

14523-22-9

≥97%

Rh–CO/Cl-bridged platform; used for carbonylation mechanism studies or to build Rh–CO active species

Rh(I) special “scorpionate” ligand platform (Tp type)

T282823

[Hydridotris(3,5-dimethyl-1H-pyrazolyl)borato]bis(triphenylphosphine)rhodium(I) toluene adduct

341483-76-9

≥99%

Tp-type platform stabilizes Rh(I); used for small-molecule activation, mechanism, and coordination-chemistry benchmarking

Rh(I) bisphosphine cationic platform (dppb type)

B775166

Rhodium(I) 1,4-bis(diphenylphosphino)butane tetrafluoroborate (contains CHCl)

79255-71-3

≥98%

General bisphosphine–Rh(I) platform for homogeneous hydrogenation/addition/isomerization system setup

Rh(I) NBD + bisphosphine platform

B139300

(Bicyclo[2.2.1]hepta-2,5-diene)[1,4-bis(diphenylphosphino)butane]rhodium(I) tetrafluoroborate

82499-43-2

≥95%

NBD is easily replaced; suitable for quickly generating bisphosphine–Rh(I) active centers and benchmarking conditions

Rh(I) ferrocene bisphosphine platform

B282815

1,1′-Bis(diisopropylphosphino)ferrocene (1,5-cyclooctadiene)rhodium(I)

157772-65-1

≥98%

Ferrocene-based bisphosphine–Rh(I) platform; used for ligand-effect studies and building homogeneous catalytic systems

Rh(I) specialty phosphine/aminophosphine platform

D282812

3-Diisopropylphosphino-2-(N,N-dimethylamino)-1H-indene (1,5-cyclooctadiene)rhodium(I)

540492-55-5

≥95%

Specialty tunable electronic/steric ligand–Rh(I); useful for “difficult substrate” screening and activation-pathway exploration

Polymer-supported Rh(I) (recyclable)

T487001

Triphenylphosphine(norbornadiene)rhodium(I) tetrafluoroborate, polymer-bound Fibre-cat®

305367-01-5

Facilitates separation/recycling and reuse; suitable for scale-up/flow chemistry or for lowering metal residues

Table C | Chiral Rh(I) (Asymmetric Hydrogenation/Additions, etc.): Pre-formed Chiral Ligand–Rh(I) Platforms

Category

Aladdin Cat. No.

Product name

CAS No.

Spec./Purity

Key features / typical uses

Chiral Rh(I)–DUPHOS (BF₄⁻)

B282816

(R,R)-i-Pr-DUPHOS-Rh(COD)BF

569650-64-2

≥98%

Pre-formed chiral bisphosphine–Rh(I); commonly used for asymmetric hydrogenation (fast to deploy; convenient for substrate screening)

Chiral Rh(I)–DUPHOS (BF₄⁻)

B359399

(S,S)-i-Pr-DUPHOS-Rh(COD)BF

≥98%

Enantiomer of i-Pr-DUPHOS version; used for ee benchmarking and condition optimization

Chiral Rh(I)–DUPHOS (OTf)

B282803

(R,R)-Et-DUPHOS-Rh(COD)OTf

136705-77-6

≥98%

OTf is weakly coordinating and often favors activation; used for asymmetric hydrogenation/addition screening

Chiral Rh(I)–DUPHOS (BF₄⁻)

B282801

(R,R)-Et-DUPHOS-Rh(COD)BF

228121-39-9

≥98%

BF₄⁻ version useful for anion-effect comparisons (activity/solubility/selectivity)

Chiral Rh(I)–DUPHOS (OTf)

B282807

(S,S)-Me-DUPHOS-Rh(COD)OTf

136705-75-4

≥98%

Me-DUPHOS platform; used to build steric/electronic gradients in asymmetric hydrogenation

Chiral Rh(I)–BPE (BF₄⁻)

B282814

(S,S)-Ph-BPE-Rh(COD)BF

849950-53-4

≥98%

BPE family often delivers high ee in asymmetric hydrogenation; suitable for screening acrylic acid/amides and related substrates

Chiral Rh(I)–BPE (BF₄⁻)

B282809

(S,S)-Me-BPE-Rh(COD)BF

213343-65-8

≥98%

Substituent changes tune sterics/electronics; used to optimize ee and activity

Chiral Rh(I)–phospholane

B282802

Rh(I)(COD) BF complex of 1,2-bis[(2S,5S)-diethylphospholanyl]benzene

213343-64-7

≥98%

Phospholane ligands often give strong stereocontrol; used for quick library building in asymmetric hydrogenation/addition

Pre-formed chiral bisphosphine cationic Rh(I)

B472689

(+)-1-Benzyl-[(3R,4R)-bis(diphenylphosphino)]pyrrolidine (1,5-cyclooctadiene)rhodium(I) tetrafluoroborate

99143-48-3

≥98%

Rigid chiral scaffold bisphosphine–Rh(I); used for asymmetric hydrogenation and stereochemical induction studies

Chiral Rh(I)–phosphacycle (DuPhos-style)

B282813

()-1,2-bis((2R,5R)-2,5-diphenylphospholane)ethane (1,5-cyclooctadiene)rhodium(I) tetrafluoroborate

528565-84-6

≥98%

One classic asymmetric hydrogenation platform; suitable for substrate-window screening and ee optimization

Chiral Rh(I)–phosphacycle (iPr version)

B590611

1,2-bis((2R,5R)-2,5-diisopropylphospholane)ethane (cyclooctadiene)rhodium(I) tetrafluoroborate

895541-38-5

≥98%

More sterically demanding version; used to adjust/improve ee and activity (substrate matching dependent)

Chiral Rh(I) bisphosphine (name truncated as provided)

B282808

1,2-bis[(2R,5R)-2,5-(dimethylphos…)]ethane (cyclooctadiene) rhodium(I) tetrafluoroborate

305818-67-1

≥98%

Chiral bisphosphine–Rh(I) platform for asymmetric hydrogenation/addition screening (name kept as in source)

Chiral Rh(I) bisphosphine (OTf)

B282806

1,2-bis[(2R,5R)-2,5-dimethylphosph…]benzene (cyclooctadiene) rhodium(I) triflate

187682-63-9

≥98%

OTf weakly coordinating; used to build more readily activated chiral Rh(I) systems

Chiral Rh(I) bisphosphine (OTf)

B359397

1,2-bis[(2S,5S)-2,5-diethylphospholanyl]benzene (1,5-cyclooctadiene) rhodium(I) triflate

142184-30-3

≥98%

Uses configuration/alkyl differences for ee/rate comparisons and optimization

Chiral Rh(I) bisphosphine (BF₄⁻)

B282805

1,2-bis[(2S,5S)-2,5-dimethylphosph…]benzene (cyclooctadiene) rhodium(I) tetrafluoroborate

205064-10-4

≥98%

BF₄⁻ version; convenient for anion-effect controls and process condition optimization

Chiral Rh(I) bisphosphine (BF₄⁻)

B282804

()-1,2-bis((2R,5R)-2,5-dimethylphospholane)benzene (cyclooctadiene)rhodium(I) tetrafluoroborate

210057-23-1

≥95%

Chiral bisphosphine platform; common for benchmarking/optimization in asymmetric hydrogenation

Chiral Rh(I) arylphosphine platform

R118527

(R,R)-()-1,2-bis[(o-methoxyphenyl)(phenyl)phosphino]ethane (1,5-cyclooctadiene)rhodium(I) tetrafluoroborate

56977-92-5

≥95%

Aryl substitution can strongly affect ee; suitable for electronic/steric ligand-effect screening

Chiral Rh(I)–NORPHOS

R282810

(R,R)-NORPHOS-Rh(COD)BF

521272-85-5

≥97%

NORPHOS chiral bisphosphine–Rh(I) platform; commonly used to build asymmetric hydrogenation systems

Chiral Rh(I)–NORPHOS

S282811

(S,S)-NORPHOS-Rh(COD)BF

78355-59-6

≥97%

Enantiomer control; used to assess ee and condition sensitivity

Chiral Rh(I)–BINAP-type

S282821

(S,S)-BINAP-type (o-methoxyphenyl/phenylphosphine) Rh(I)(COD) BF

71423-54-6

≥95%

Classic BINAP-family platform; applicable to asymmetric hydrogenation/addition, convenient for literature benchmarking

Chiral Rh(I) [2.2]paracyclophane bisphosphine (R)

R282822

(R)-[2.2]paracyclophane (COD)BF₄–Rh(I)

1038932-67-0

≥97%

Rigid scaffold supports stereocontrol; used for high-selectivity asymmetric hydrogenation/addition exploration

Chiral Rh(I) phane bisphosphine (R)

R282817

(R)-[2.2]paracyclophane (phane) bisphosphine (COD)BF₄–Rh(I)

619334-93-9

≥97%

Rigid “phane” bisphosphine platform; used for high-ee asymmetric hydrogenation/addition screening

Chiral Rh(I) paracyclophane bisphosphine (R)

R282819

(R)-[2.2]paracyclophane bisphosphine (COD)BF₄–Rh(I)

849950-56-7

≥97%

Rigid paracyclophane framework; useful for optimizing “stereochemical environment → ee response”

Chiral Rh(I) phane bisphosphine (S)

S282818

(S)-[2.2]paracyclophane phane bisphosphine (COD)BF₄–Rh(I)

1174218-30-4

≥97%

Enantiomer version; used for enantioselectivity comparisons

Chiral Rh(I) paracyclophane bisphosphine (S)

S282820

(S)-[2.2]paracyclophane bisphosphine (COD)Rh(I)

200808-73-7

≥97%

Same series (S) enantiomer; used for ee/activity comparison and optimization

Chiral Rh(I) “bipyridine/bisphosphine” (R)

R282838

(R)-Bipyridine/bisphosphine-type (COD)BF₄–Rh(I)

573718-56-6

≥97%

Hybrid-ligand platform; useful for library screening and structure–selectivity relationship studies

Chiral Rh(I) “bipyridine/bisphosphine” (S)

S282839

(S)-Bipyridine/bisphosphine-type (COD)BF₄–Rh(I)

1174131-02-2

≥97%

Enantiomer control; used for ee/substrate-window optimization

Chiral Rh(I) ferrocene bisphosphine (R,R)

B282842

1,1′-Bis((2R,5R)-2,5-diethylphosphino)ferrocene (COD) rhodium(I) tetrafluoroborate

162412-90-0

≥95%

Ferrocene-based chiral platform; widely used for stereocontrol in asymmetric hydrogenation/addition

Chiral Rh(I) ferrocene bisphosphine (R,R)

B282824

1,1′-Bis((2R,5R)-2,5-diisopropylphosph… )ferrocene (COD) rhodium(I) tetrafluoroborate

849773-96-2

≥95%

Bulkier version; used to enhance stereocontrol or improve substrate matching

Chiral Rh(I) ferrocene bisphosphine (R,R)

B282849

1,1′-Bis((2R,5R)-2,5-dimethylphosphino)ferrocene (COD) rhodium(I) tetrafluoroborate

854275-87-9

≥95%

Less bulky version; useful for steric-gradient building to optimize ee/activity

Chiral Rh(I) ferrocene bisphosphine (S,S)

B282843

1,1′-Bis((2S,5S)-2,5-diethylphosphino)ferrocene (COD) rhodium(I) tetrafluoroborate

290347-88-5

≥95%

Enantiomer control; used for ee benchmarking and optimization

Chiral Rh(I) ferrocene bisphosphine (S,S)

B282846

1,1′-Bis((2S,5S)-2,5-diisopropylphosph… )ferrocene (COD) rhodium(I) tetrafluoroborate

854920-94-8

≥95%

Bulkier enantiomer; used for optimization and controls

Chiral Rh(I) ferrocene bisphosphine (S,S)

B282850

1,1′-Bis((2S,5S)-2,5-dimethylphosphino)ferrocene (COD) rhodium(I) tetrafluoroborate

854920-90-4

≥95%

Less bulky enantiomer; used to build steric gradients

Chiral Rh(I) bisphosphine (BF₄⁻)

B282841

1,2-bis((2R,5R)-2,5-diethylphosphino)ethane (COD) rhodium(I) tetrafluoroborate

136705-70-9

≥95%

Chiral bisphosphine–Rh(I) platform for asymmetric hydrogenation substrate screening and ee optimization

Chiral Rh(I) bisphosphine (BF₄⁻)

B282844

1,2-bis((2R,5R)-2,5-diisopropylphosph… )ethane (COD) rhodium(I) tetrafluoroborate

136705-72-1

≥95%

Version differing in sterics/electronics; used to tune ee/activity and substrate fit

Chiral Rh(I) bisphosphine (BF₄⁻)

B282845

1,2-bis((2S,5S)-2,5-diisopropylphosph… )ethane (COD) rhodium(I) tetrafluoroborate

213343-67-0

≥95%

Enantiomer version; used for controls and optimization

Commercial pre-formed chiral Rh(I) (catASium®)

B282827

catASium® MNN(R)Rh(COD)BF

908128-78-9

≥95%

“Plug-and-play” pre-formed system; suitable for rapid feasibility checks in asymmetric hydrogenation/addition

Chiral Rh complex (BOX/related)

B405175

Bis(acetato)[(S,S)-4,6-bis(4-isopropyl-2-oxazolin-2-yl)-m-xylene]rhodium

929896-28-6

Chiral oxazoline-ligand Rh platform; used for screening in asymmetric addition/cyclization (reaction-dependent)

Chiral Rh(I) bisphosphine–diene platform

B120916

(S,S)-1,2-bis[(tert-butyl)methylphosphino]ethane [η-(2,5-bicycloheptadiene)] rhodium(I) tetrafluoroborate

203000-59-3

Chiral bisphosphine + diene cationic Rh(I) platform; used to explore ligand effects in asymmetric hydrogenation/addition

Table D | Rh(II) Dirhodium (Achiral): General Systems for Carbene Transfer/Insertion

Category

Aladdin Cat. No.

Product name

CAS No.

Spec./Purity

Key features / typical uses

Rh(II) dirhodium carboxylate (OAc)

R102671

Dirhodium(II) tetraacetate

15956-28-2

Rh 43.0%–46.6%

Classic dirhodium carbene-transfer catalyst; widely used for cyclopropanation, C–H insertion, X–H insertion, etc.

Rh(II) dirhodium carboxylate (TFA)

R118543

Dirhodium(II) tetratrifluoroacetate

31126-95-1

Rh 27.5–35.0%

More electron-withdrawing variant; often used for higher activity or altered selectivity in carbene transfer

Rh(II) dirhodium carboxylate (octanoate)

R113304

Dirhodium(II) octanoate

73482-96-9

Rh ≥25.0%

More hydrophobic and often more soluble in organic media; suitable for carbene transfer in organic-solvent systems

Rh(II) dirhodium carboxylate (pivalate)

R465789

Dirhodium(II) pivalate (dimer)

62728-88-5

≥99.9% metals basis

Bulkier carboxylate; often used to tune selectivity in carbene transfer reactions

Rh(II) dirhodium carboxylate (TPA)

R167247

Dirhodium(II) tetrakis(triphenylacetate) (Rh(TPA))

142214-04-8

≥99%

Aromatic bulky carboxylate; used to modulate selectivity and substrate matching in carbene transfer

Rh(II) dirhodium perfluorocarboxylate

R338680

Dirhodium(II) heptafluorobutyrate (dimer)

73755-28-9

≥97%

Strongly electron-withdrawing perfluorocarboxylate; used to explore more reactive/strongly driven carbene-transfer systems

Rh(II) dirhodium aromatic carboxylate

T299618

Tetrakis(triphenylacetato)dirhodium

68803-79-2

≥97%

Aromatic bulky carboxylate; used for selectivity optimization and mechanistic comparisons in carbene transfer

Rh(II) dirhodium (lactam ligand)

B301149

Dirhodium(II) tetracaprolactamate

138984-26-6

≥95%

Classic Rh(caprolactamate); often used for robust, reproducible carbene transfer

Dinuclear Rh carboxylate complex

B152255

Bis[(α,α,α′,α′-tetramethyl-1,3-benzenedipropionate)rhodium]

819050-89-0

≥96% (HPLC)

Dinuclear carboxylate platform; used for reactivity/selectivity benchmarking and exploratory catalysis studies

Table E | Chiral Rh(II) Dirhodium: Asymmetric Carbene Transfer (Cyclopropanation / C–H & X–H Insertion, etc.)

Category

Aladdin Cat. No.

Product name

CAS No.

Spec./Purity

Key features / typical uses

Chiral Rh(II) dirhodium (amino-acid-derived)

T406155

Tetrakis[N-tetrafluorophthalimido-(R)-tert-leucinate]dirhodium, bis(ethyl acetate) adduct

≥98% (HPLC)

Common in asymmetric carbene transfer; used for enantioselective cyclopropanation and insertion reactions

Chiral Rh(II) dirhodium (amino-acid-derived)

T406154

Same as above (S-tert-leucine) adduct

≥98% (HPLC)

Enantiomer control; used for ee optimization and substrate matching

Chiral Rh(II) dirhodium (halogenated aroyl tuning)

T405008

Tetrakis[N-tetrachlorophthalimido-(R)-tert-leucinate]dirhodium adduct

2001054-66-4

≥98% (HPLC)

Halogenated aroyl group tunes electronics/sterics; used for selectivity optimization in asymmetric carbene transfer

Chiral Rh(II) dirhodium (homologous control)

T121192

Same as above (R-tert-leucine) adduct

≥98%

Chiral dirhodium platform; used for benchmarking and scale-up verification in asymmetric carbene transfer

Chiral Rh(II) dirhodium (S series)

T121194

Tetrakis[N-tetrafluorophthalimido-(S)-tert-leucinate]dirhodium adduct

564450-56-2

≥98%

S-configuration platform; used for enantioselectivity comparisons and ee optimization

Chiral Rh(II) dirhodium (S series)

T121191

Same as above (S-tert-leucine) adduct

515876-71-8

≥98%

S-series chiral dirhodium; suitable for building “enantiomer–conditions–selectivity” comparison matrices

Chiral Rh(II) dirhodium (tetrachloroaroyl, S)

T406153

Tetrakis[N-tetrachlorophthalimido-(S)-tert-leucinate]dirhodium adduct

≥95% (HPLC)

Adds an electronics/sterics gradient; used for optimizing asymmetric carbene transfer

Chiral Rh(II) dirhodium (Phe-derived)

T121173

Tetrakis[N-phthalimido-(S)-phenylalaninate]dirhodium, ethyl acetate adduct

131219-55-1

Amino-acid-derived chiral dirhodium; used for screening asymmetric carbene transfer reactions

Chiral Rh(II) dirhodium (DOSP series)

T282836

Rh(R-DOSP)

178879-60-2

≥95%

Widely used in asymmetric carbene transfer; for high-ee cyclopropanation/insertion

Chiral Rh(II) dirhodium (BTPCP series)

T282834

[Rh(R-BTPCP)]

1345974-62-0

≥95%

BTPCP family; suitable when seeking stronger stereocontrol in carbene transfer

Chiral Rh(II) dirhodium (PTAD series)

T282832

[Rh(R-PTAD)]

909393-65-3

≥95%

PTAD family; used for enantioselective cyclopropanation and C–H insertion

Chiral Rh(II) dirhodium (BTPCP, specific ligand form)

T282835

Tetrakis[[S]-(+)-[(1S)-1-(4-bromophenyl)-2,2-diphenylcyclopropanecarboxylate]]dirhodium(II) [Rh(S-BTPCP)]

1345974-63-1

≥95%

Specific BTPCP variant; for fine-tuning selectivity and substrate scope

Chiral Rh(II) dirhodium (PTAD, specific ligand form)

T282833

Tetrakis[[S]-(+)-(1-adamantyl)-(N-phthalimido)acetate]]dirhodium(II) [Rh(S-PTAD)]

909389-99-7

≥95%

Specific PTAD variant; used to fine-tune enantioselectivity and activity

Chiral Rh(II) dirhodium (DOSP, specific ligand form)

T282837

Tetrakis[[S]-()-N-(p-dodecylphenylsulfonyl)prolinate]dirhodium(II) Rh(S-DOSP)

179162-34-6

≥95%

Specific DOSP variant; long-chain substitution may affect solubility/microenvironment and thus selectivity

Table F | Cp*/C–H Activation and Cyclometalated Rh Platforms

Category

Aladdin Cat. No.

Product name

CAS No.

Spec./Purity

Key features / typical uses

Cp*Rh(III)Cl dimer precursor

P284028

Dichloro(pentamethylcyclopentadienyl)rhodium(III) dimer

12354-85-7

≥99.95% metals basis

Cp*Rh(III) C–H activation “workhorse”; used for directed C–H activation/cyclization/coupling, etc.

Cp*Rh(III) halide-free cationic precursor

T282840

Tris(acetonitrile)(pentamethylcyclopentadienyl)rhodium(III) hexafluoroantimonate

125357-42-8

≥98%

Halide-free with weakly coordinating anion; used for “cleaner” Cp*Rh(III) activation and mechanistic benchmarking

Substituted Cp–Rh(III)Cl dimer

B405459

[1,3-Bis(ethoxycarbonyl)-2,4,5-trimethylcyclopentadien-1-yl]rhodium(III) dichloride dimer

1352745-18-6

≥95% (T)

Cp substitution tunes electronics/sterics; used to modulate reactivity and selectivity in C–H activation systems

Cp*Rh(I)(CO) precursor

D282826

Dicarbonyl(pentamethylcyclopentadienyl)rhodium(I)

32627-01-3

≥99%

Cp*Rh platform interconversion precursor; suitable for organometallic/mechanistic and ligand-exchange studies

Cyclometalated Rh(III) dimer (C^N)

C472408

Chloro-bis(2-phenylpyridine)rhodium(III) dimer

33915-80-9

≥98%

Typical C^N cyclometalated Rh(III) platform; used for cyclometalated complex studies/materials and related catalytic exploration

Table G | Clusters / CO Clusters and Hydride Clusters (Mechanistic Models / Cluster Precursors)

Category

Aladdin Cat. No.

Product name

CAS No.

Spec./Purity

Key features / typical uses

Rh carbonyl cluster (Rh)

H485521

Hexarhodium hexadecacarbonyl (Rh(CO)₁₆)

28407-51-4

Rh 57–60%

Representative carbonyl cluster; used as a cluster/nano-Rh precursor and for CO coordination and mechanistic studies

Rh carbonyl cluster (Rh)

T132698

Tetrarhodium dodecacarbonyl (Rh(CO)₁₂)

19584-30-6

≥98%

Classic Rh(CO)₁₂; used in carbonyl cluster chemistry, mechanistic models, and precursor exploration

Rh hydride cluster (Rh₄–H)

T282831

Tetrakis(1,5-cyclooctadiene) tetra-μ-hydrido tetrarhodium

82660-97-7

≥98%

Hydride-cluster model; used for hydrogen transfer/hydrogenation mechanism studies and exploratory reaction platforms

 

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Cite this article

Aladdin Scientific. "Making Sense of Rhodium Catalysis: Three Core Engines—Rh(I), Rh(II), and Cp*Rh(III)—plus a Quick Selection Guide to Representative Product Tables A–G" Aladdin Knowledge Base, updated 29 dic 2025. https://www.aladdinsci.com/us_es/faqs/making-sense-of-rhodium-catalysis-en.html
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