Professor Reich is no longer taking students.
My research effort has been directed toward the study of organometallic and organometalloid compounds with the goal of deepening our understanding of these materials and thus improve and extend their chemistry.
Most carbon-carbon bond forming processes involve the interaction of carbanionic centers with carbon electrophiles like carbonyl compounds, epoxides, aziridines, alkyl halides, activated alkenes and many others. Organolithium reagents are probably the single most important source of carbanionic species, both directly as well as indirectly as precursors to other organometallic reagents (Cu, B, Si, Sn, etc). They have long played an important role in synthetic organic chemistry, and a vast literature provides many complex recipes for preparing and utilizing them. However, the basis for much of what we do in the laboratory when we prepare and use lithium reagents is empirical rather than based on firm mechanistic and structural insights. We are trying to replace the “art” in the chemistry of these organometallic reagents with science.
Some of the reactivity issues we have been interested in are the following: What determines whether an organometallic reagent adds 1,2 or 1,4 to an α,β-unsaturated carbonyl compound? Why do lithium halides sometimes have such dramatic effects on organolithium reactions? What role does catalysis by lithium cation play in reactions? What intermediate species are formed during lithium-metalloid exchange reactions and transmetalations and what are their reactivities? What role do different organolithium aggregates play in the selectivity and reactivity of these reagents? How do coordinating solvents and co-solvents such as THF, TMEDA, HMPA, crown ethers and others play their important roles in fine tuning the stereochemistry and regiochemical selectivity of organolithium reagents? How do chelating appendages affect structure and reactivity? What factors influence the configurational stability of organolithium reagents?
The key to unraveling these complexities lies in understanding the organolithium reagents themselves. We perform extensive multinuclear variable temperature NMR studies of organolithium solutions to establish Li-C connectivity, aggregation state, and the dynamics of species interconversion as a function of solvent and solvent additive. These are combined with kinetic studies using a recently developed Rapid Injection NMR apparatus which allows determination of reaction rates on a time scale of seconds at temperatures as low as -135 C. This apparatus allowed some of the first accurate measurements of the reactivity of individual organolithium aggregates towards common electrophiles, as well as the reactivities of individual conformational isomers of an amide.
Awards and Honors
|James Flack Norris Award in Physical Organic Chemistry||2011|
|Arfvedson-Schlenk Prize in Lithium Chemistry, German Chemical Society||2007|
|Evan P. Helfaer Professor of Chemistry, University of Wisconsin-Madison||1996|
|University of Wisconsin Mid-Career Award||1996|
|Upjohn Teaching Award, University of Wisconsin||1994|
|Role of Organolithium Aggregates and Mixed Aggregates in Organolithium Mechanisms. Chemical Reviews. 2013;113:7130-7178..|
|What's Going on with These Lithium Reagents?. Journal of Organic Chemistry. 2012;77:5471-5491..|
|Mechanistic Studies of the Lithium Enolate of 4-Fluoroacetophenone: Rapid-Injection NMR Study of Enolate Formation, Dynamics, and Aldol Reactivity. Journal of the American Chemical Society. 2011;133:16774-16777..|
|Structure and Dynamics of alpha-Aryl Amide and Ketone Enolates: THF, PMDTA, TMTAN, HMPA, and Crypt-Solvated Lithium Enolates, and Comparison with Phosphazenium Analogues. Journal of Organic Chemistry. 2010;75:6163-6172..|
|Multinuclear NMR Study of the Solution Structure and Reactivity of Tris(trimethylsilyl)methyllithium and its Iodine Ate Complex. Journal of Organic Chemistry. 2009;74:719-729..|