12081-22-0 | Crotylpalladium chloride dimer

Packsize	Purity	Availability	Price	Discounted Price
100mg	98%	in stock	$24.00	$17.00
250mg	98%	in stock	$42.00	$30.00
500mg	98	in stock	$81.00	$57.00
1g	98	in stock	$120.00	$84.00
5g	98%	in stock	$501.00	$351.00

Description

• Catalog Number: AB54824
• Chemical Name: Crotylpalladium chloride dimer
• CAS Number: 12081-22-0
• Molecular Formula: C8H14Cl2Pd2
• Molecular Weight: 393.9428
• MDL Number: MFCD01074457
• SMILES: [Pd+]C/C=C/C.[Pd+]C/C=C/C.[Cl-].[Cl-]

Computed Properties

• Complexity: 26.7
• Covalently-Bonded Unit Count: 4
• Defined Bond Stereocenter Count: 2
• Heavy Atom Count: 12
• Hydrogen Bond Acceptor Count: 2

Upstream Synthesis Route

(2-Butenyl)chloropalladium dimer is a versatile compound commonly used in chemical synthesis for its unique properties and reactivity. This dimer serves as a valuable palladium source in various organic reactions, particularly in cross-coupling reactions and catalysis.In the realm of chemical synthesis, (2-Butenyl)chloropalladium dimer acts as a key catalyst in the formation of carbon-carbon and carbon-heteroatom bonds. It is commonly employed in Heck, Suzuki, Sonogashira, and Stille coupling reactions, enabling the efficient construction of complex organic molecules. The dimer's palladium center facilitates the activation of carbon-halogen bonds, promoting the coupling of diverse functional groups and substrates.Furthermore, (2-Butenyl)chloropalladium dimer exhibits high stability and compatibility with a wide range of reaction conditions, making it a preferred choice for synthetic chemists seeking efficient and selective transformations. Its ability to mediate challenging bond-forming processes has positioned it as a valuable tool in modern organic synthesis, offering enhanced control over regioselectivity and stereoselectivity.Overall, the application of (2-Butenyl)chloropalladium dimer in chemical synthesis serves as a cornerstone for accessing novel molecular architectures and advancing the field of organic chemistry. By harnessing its catalytic potential, researchers can expedite the synthesis of pharmaceuticals, agrochemicals, and materials with tailored properties, paving the way for innovative discoveries and applications in the realm of molecular design and synthesis.