Stahl oxidation
The Stahl oxidation is a copper-catalyzed aerobic oxidation of primary and secondary alcohols to aldehydes and ketones. Known for its high selectivity and mild reaction conditions, the Stahl oxidation offers several advantages over classical alcohol oxidations.
Key features of the Stahl oxidation are the use of a 2,2'-bipyridyl-ligated copper species in the presence of a nitroxyl radical and N-methyl imidazole in polar aprotic solvent, most commonly acetonitrile or acetone. Copper sources can vary, though sources with non-coordinating anions like triflate, tetrafluoroborate, and hexafluorophosphate are preferred, with copper(I) bromide and copper(I) iodide salts demonstrating utility in select applications. Frequently, tetrakis(acetonitrile)copper(I) salts are used. For most applications, reactions can be run at room temperature and ambient air contains sufficiently high enough oxygen concentrations to be used as the terminal oxidant. Compared to chromium-, DMSO-, or periodinane-mediated oxidations, this proves safe, environmentally-friendly, practical, and highly economical.
In general, the Stahl oxidation is selective for oxidizing primary alcohols over secondary alcohols, and favors the oxidation of primary benzylic alcohols over primary aliphatic alcohols when TEMPO is used as the nitroxyl radical. This is in contrast to the Oppenauer oxidation, which favors the oxidation of secondary alcohols over primary and several other specialty oxidations. Over-oxidation of primary alcohols to carboxylic acids is rare, though lactones can form in certain diol-containing substrates. The use of less hindered nitroxyl radicals like ABNO or AZADO allow for the oxidation of both primary and secondary alcohols.
History
In 2011, Jessica Hoover and Shannon Stahl disclosed improved conditions for selective oxidation of primary alcohols to aldehydes using a copper/TEMPO system. While several catalytic aerobic oxidation systems were known at the time, many utilized palladium, which can be prohibitive through its expense and its cross-reactivity with alkene-bearing substrates. Aerobic oxidative catalysis of alcohols by copper, though known since at least 1984, was generally lower performing, requiring some combination of elevated reaction temperatures, higher catalyst loading, handling of pure oxygen, and biphasic or otherwise non-common solvent systems.Following the success of this initial disclosure, Hoover and Stahl went on to publish a further simplified protocol for rapid benzylic alcohol oxidation with Nicolas Hill, director of undergraduate organic chemistry laboratories at the University of Wisconsin - Madison. Utilizing a less expensive solvent and copper source, Hill, Hoover, and Stahl demonstrated that higher catalyst loadings could be economically achieved. In doing so, the oxidation of alcohols could be accelerated for use as a practical educational tool in undergraduate labs. Furthermore, reaction completion is typically indicated by a change in solution color for red/brown to green resulting from a change in the copper species' resting state. This is unique for benzylic and other activated alcohols, as the rate-limiting-step for these substrates is catalyst re-oxidation, which differs from aliphatic alcohols where the rate limiting step is C-H cleavage. The Stahl oxidation is a component of the undergraduate organic chemistry laboratory curriculum at UW-Madison and the University of Utah.
In 2013, the mechanism for the copper/TEMPO oxidation of alcohols was elucidated, and it was found the use of less hindered nitroxyl radical sources allowed for the oxidation of secondary alcohols.