Palladium diacetate
[CAS# 3375-31-3]

Identification

• Classification: Organic raw materials >> Organometallic compound >> Organic palladium
• Name: Palladium diacetate
• Synonyms: Palladium(II) acetate
• Molecular Formula: Pd^.(C₂H₃O₂)₂
• Molecular Weight: 224.51
• CAS Registry Number: 3375-31-3 (19807-27-3)
• EC Number: 222-164-4
• SMILES: CC(=O)[O-].CC(=O)[O-].[Pd+2]

Properties

• Melting point: 205 ºC
• Water solubility: insoluble

Safety Data

• Hazard Symbols: GHS05;GHS07;GHS09 Danger
• Hazard Statements: H302-H317-H318-H400-H410
• Precautionary Statements: P261-P264-P264+P265-P270-P272-P273-P280-P301+P317-P302+P352-P305+P354+P338-P317-P321-P330-P333+P317-P362+P364-P391-P501

Hazard Classification

Hazard	Class	Category Code	Hazard Statement
Serious eye damage	Eye Dam.	1	H318
Skin sensitization	Skin Sens.	1	H317
Chronic hazardous to the aquatic environment	Aquatic Chronic	1	H410
Acute hazardous to the aquatic environment	Aquatic Acute	1	H400
Acute toxicity	Acute Tox.	4	H302
Substances or mixtures corrosive to metals	Met. Corr.	1	H290
Chronic hazardous to the aquatic environment	Aquatic Chronic	4	H413
Skin sensitization	Skin Sens.	1A	H317
Eye irritation	Eye Irrit.	2	H319
Chronic hazardous to the aquatic environment	Aquatic Chronic	2	H411
Specific target organ toxicity - single exposure	STOT SE	3	H335
Skin irritation	Skin Irrit.	2	H315

Discovory and Applicatios

Palladium diacetate, commonly referred to as Pd(OAc)₂, is an important palladium compound with the molecular formula Pd(C₂H₃O₂)₂. This compound consists of a palladium atom coordinated to two acetate groups, making it a highly reactive and versatile precursor for various catalytic processes. Since its discovery and isolation in the mid-20th century, palladium diacetate has become a key player in homogeneous catalysis, particularly in organic synthesis.

The discovery of palladium diacetate can be traced to the growing interest in palladium-based catalysts in the 1950s and 1960s, a time when researchers were searching for new palladium complexes that could promote organic transformations under milder conditions. Palladium diacetate was found to be particularly effective due to its solubility in organic solvents and its ability to dissociate easily into reactive palladium species. This opened the door to its widespread use in a variety of catalytic reactions.

One of the most significant applications of palladium diacetate is in carbon-carbon bond-forming reactions, such as the Heck, Suzuki-Miyaura, and Stille reactions. These cross-coupling reactions are central to modern organic synthesis and allow for the construction of complex molecules used in pharmaceuticals, agrochemicals, and materials science. In the Heck reaction, for example, palladium diacetate serves as the catalyst for coupling aryl halides with alkenes, facilitating the formation of substituted alkenes. This reaction is widely used in the synthesis of fine chemicals and active pharmaceutical ingredients (APIs).

Palladium diacetate is also employed in the Wacker process, a prominent industrial reaction for converting ethylene to acetaldehyde via palladium-catalyzed oxidation. This reaction is significant in the large-scale production of acetaldehyde, which serves as a key building block for numerous chemical products, including plastics, paints, and adhesives. The role of palladium diacetate in the Wacker process underscores its importance in industrial applications.

Another notable application of palladium diacetate is in C-H activation chemistry, a field that has gained considerable attention for its potential to streamline synthetic routes by directly functionalizing carbon-hydrogen bonds. Palladium diacetate is often used as a catalyst in these reactions due to its ability to facilitate the activation of C-H bonds under relatively mild conditions. This has led to more efficient methods for constructing complex organic frameworks, reducing the need for pre-functionalized starting materials and improving the overall sustainability of chemical processes.

Palladium diacetate's utility extends beyond its role in carbon-carbon bond formation and C-H activation. It is also employed in a range of other catalytic processes, such as hydrogenation, carbonylation, and oxidation reactions. For example, in selective oxidation reactions, palladium diacetate can catalyze the oxidation of alcohols to aldehydes or ketones with high selectivity, making it a valuable tool for fine chemical production.

Despite its wide applicability, palladium diacetate presents certain challenges, particularly in terms of stability and handling. The compound is sensitive to air and moisture, and it can degrade over time if not stored properly. However, its reactivity and versatility in catalysis outweigh these limitations, and it remains a staple in the toolkit of synthetic chemists and industrial researchers alike.

In conclusion, palladium diacetate is a compound of immense importance in both academic and industrial chemistry. Its discovery and subsequent application in numerous catalytic processes, particularly in carbon-carbon bond formation and oxidation reactions, have made it a vital component of modern organic synthesis. Its role in pharmaceuticals, fine chemicals, and industrial production continues to drive research and innovation in the field of palladium catalysis.

References

2021. Palladium-Catalyzed Annulations of Strained Cyclic Allenes. Journal of the American Chemical Society, 143(26).
DOI: 10.1021/jacs.1c04896

2020. Can Donor Ligands Make Pd(OAc)2 a Stronger Oxidant? Access to Elusive Palladium(II) Reduction Potentials and Effects of Ancillary Ligands via Palladium(II)/Hydroquinone Redox Equilibria. Journal of the American Chemical Society, 142(46).
DOI: 10.1021/jacs.0c09464

2005. Efficient batch and continuous flow Suzuki cross-coupling reactions under mild conditions, catalysed by polyurea-encapsulated palladium (ii) acetate and tetra-n-butylammonium salts. Chemical Communications, (16).
DOI: 10.1039/b418669a