Cross-coupling reaction: Difference between revisions

Cross-coupling reactions are a family of organic chemical reactions that are pivotal in the formation of carbon-carbon (C-C) bonds, an essential process in the synthesis of complex organic compounds. These reactions involve the coupling of two different types of organic halides or pseudohalides, typically facilitated by a metal catalyst. The most common metals used in these reactions are palladium (Pd) and nickel (Ni), which act as a catalyst to enable the bond formation between the electrophile and the nucleophile.

Overview[edit]

Cross-coupling reactions are widely utilized in the pharmaceutical, agricultural, and materials science industries due to their efficiency and versatility in forming C-C bonds. The ability to join two carbon atoms from different molecules has profound implications for the construction of complex molecular architectures found in natural products, medicines, and organic materials.

Types of Cross-Coupling Reactions[edit]

Several types of cross-coupling reactions have been developed, each named after their discoverers or the specific characteristics of the reaction. Some of the most significant include:

• Suzuki coupling: Involves the coupling of an organoboron compound with an organohalide, using a palladium catalyst.
• Heck reaction: Couples aryl or vinyl halides with alkenes in the presence of a palladium catalyst to form substituted alkenes.
• Sonogashira coupling: A palladium-catalyzed reaction that couples terminal alkynes with aryl or vinyl halides.
• Stille coupling: Involves the coupling of organotin compounds with organohalides, catalyzed by palladium.
• Negishi coupling: Uses organozinc compounds coupled with organohalides, facilitated by a palladium or nickel catalyst.

Mechanism[edit]

The general mechanism of cross-coupling reactions involves several key steps, although the specifics can vary depending on the type of reaction and the catalyst used. The basic steps include:

1. Oxidative Addition: The metal catalyst inserts into the carbon-halogen bond of the organohalide, forming a metal-halide complex. 2. Transmetalation: The organometallic reagent (e.g., organoboron, organozinc) transfers its organic group to the metal, replacing the halide. 3. Reductive Elimination: The metal catalyst facilitates the coupling of the two organic groups to form the desired C-C bond, regenerating the catalyst in the process.

Applications[edit]

Cross-coupling reactions have revolutionized the synthesis of complex organic molecules, enabling the efficient and selective construction of C-C bonds. These reactions have found applications in:

• Synthesis of pharmaceuticals: Many drugs are synthesized or modified using cross-coupling reactions to introduce specific functional groups or to construct the core molecular framework.
• Agricultural chemicals: Synthesis of herbicides, fungicides, and insecticides often involves cross-coupling reactions to achieve the desired molecular structure.
• Materials science: Organic electronics, light-emitting diodes (LEDs), and organic photovoltaic materials are often synthesized using cross-coupling reactions to build the conjugated systems necessary for their function.

Challenges and Future Directions[edit]

Despite their widespread use, cross-coupling reactions face challenges such as the need for expensive and sometimes toxic metal catalysts, the generation of hazardous waste, and the requirement for stringent reaction conditions. Ongoing research aims to develop more sustainable and environmentally friendly cross-coupling processes, including the use of less toxic catalysts, greener solvents, and more efficient reaction pathways.

See Also[edit]

• Organic synthesis
• Catalysis
• Palladium-catalyzed coupling reactions
• Carbon-carbon bond formation

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  Katalysezyklus Kumada Kupplung
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  Sonogashira coupling mechanism
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  Buchwald-Hartwig