Shannon S. Stahl

Bio: Shannon S. Stahl is an academic researcher from University of Wisconsin-Madison. The author has contributed to research in topics: Catalysis & Alcohol oxidation. The author has an hindex of 93, co-authored 345 publications receiving 29084 citations. Previous affiliations of Shannon S. Stahl include Wisconsin Alumni Research Foundation & Great Lakes Bioenergy Research Center.

Palladium Oxidase Catalysis: Selective Oxidation of Organic Chemicals by Direct Dioxygen-Coupled Turnover

Abstract: Selective aerobic oxidation of organic molecules is a fundamental and practical challenge in modern chemistry. Effective solutions to this problem must overcome the intrinsic reactivity and selectivity challenges posed by the chemistry of molecular oxygen, and they must find application in diverse classes of oxidation reactions. Palladium oxidase catalysis combines the versatility of Pd(II)-mediated oxidation of organic substrates with dioxygen-coupled oxidation of the reduced palladium catalyst to enable a broad range of selective aerobic oxidation reactions. Recent developments revealed that cocatalysts (e.g. Cu(II), polyoxometalates, and benzoquinone) are not essential for efficient oxidation of Pd(0) by molecular oxygen. Oxidatively stable ligands play an important role in these reactions by minimizing catalyst decomposition, promoting the direct reaction between palladium and dioxygen, modulating organic substrate reactivity and permitting asymmetric catalysis.

Copper-Catalyzed Aerobic Oxidative C ? H Functionalizations: Trends and Mechanistic Insights

Abstract: The selective oxidation of C-H bonds and the use of O(2) as a stoichiometric oxidant represent two prominent challenges in organic chemistry. Copper(II) is a versatile oxidant, capable of promoting a wide range of oxidative coupling reactions initiated by single-electron transfer (SET) from electron-rich organic molecules. Many of these reactions can be rendered catalytic in Cu by employing molecular oxygen as a stoichiometric oxidant to regenerate the active copper(II) catalyst. Meanwhile, numerous other recently reported Cu-catalyzed C-H oxidation reactions feature substrates that are electron-deficient or appear unlikely to undergo single-electron transfer to copper(II). In some of these cases, evidence has been obtained for the involvement of organocopper(III) intermediates in the reaction mechanism. Organometallic C-H oxidation reactions of this type represent important new opportunities for the field of Cu-catalyzed aerobic oxidations.

Palladium(II)-Catalyzed Alkene Functionalization via Nucleopalladation: Stereochemical Pathways and Enantioselective Catalytic Applications

Abstract: The development of catalytic reactions of alkenes transformed the chemical industry in the mid-20th century. Representative reactions included hydrogenation, oxidation, hydroformylation, oligomerization and polymerization. In 1959, researchers at Wacker Chemie developed a Pd-catalyzed method for the aerobic oxidative coupling of ethylene and water to produce acetaldehyde (eq 1, Scheme 1).1,2,3 This reaction represented the starting point for the development of numerous other Pd-catalyzed reactions in subsequent decades, ranging from alkene and diene oxidation reactions to cross-coupling reactions of aryl halides. (1) Scheme 1 The Wacker Reaction. The stoichiometric oxidation of ethylene by aqueous PdII salts had been known since the 19th century;4 however, the industrial Wacker Process owes its success to the recognition that the oxidized catalyst could be regenerated by molecular oxygen in the presence of cocatalytic CuCl2 (Scheme 1). The reaction proceeds through a β-hydroxyethyl-PdII intermediate that forms via the net addition of hydroxide and Pd across the C–C double bond of ethylene. This seemingly straightforward “hydroxypalladation” step has been the subject of extensive mechanistic research and controversy over the past five decades. A major focus of this debate has centered on whether the reaction proceeds by a cis-hydroxypalladation pathway, involving migration of a coordinated water or hydroxide to the ethylene molecule (eq 2), or a trans-hydroxypalladation pathway, involving nucleophilic attack of exogenous water or hydroxide on the coordinated ethylene molecule (eq 3). The current mechanistic understanding of the hydroxypalladation step in the Wacker Process is the subject of an excellent recent review by Keith and Henry.3 (2) (3) Soon after the discovery of the Wacker process, a number of research groups demonstrated that PdII could facilitate the addition of several different nucleophiles to alkenes, and a variety of oxidative and non-oxidative C–O, C–N, and C–C bond-forming transformations have been developed, including intra- and intermolecular reactions.5 The PdII-alkyl intermediate formed in the nucleopalladation step can participate in a number of subsequent transformations (e.g., see Scheme 2). Such opportunities, together with the broad functional-group compatibility and air- and moisture-tolerance of the PdII-catalysts, enable the preparation of important organic building blocks as well as useful hetero- and carbocyclic molecules. Scheme 2 Versatility of the PdII-Alkyl Intermediate Arising from Alkene Nucleopalladation. Nucleopalladation of an alkene often generates a new stereogenic center, and the synthetic utility of the catalytic reactions is enhanced significantly if the stereochemical course of C–Nu bond formation can be controlled. Enantioselective PdII-catalyzed functionalization of alkenes has experienced considerably less success than have many other classes of enantioselective transformations, despite the extensive history of the Wacker process and related oxidation reactions. The former reactions face several challenges. Phosphine ligands, which have been highly successful in other enantioselective processes, are often incompatible with the oxidants used in these reactions (such as O2), and their σ-donating ability can attenuate the electrophilicity and/or oxidizing ability of the PdII salts. A mechanistic basis for the difficulty in achieving effective enantioselective catalysis is that nucleopalladation reactions are capable of proceeding by two stereochemically different pathways: cis- or trans-nucleopalladation (Scheme 3). Experimental results obtained over the past 40 years, especially in the last decade, demonstrate that the energy barriers associated with these different pathways can be very similar, in some cases similar enough that both pathways operate in parallel. This mechanistic scenario can increase the difficulty of achieving high levels of enantioinduction. Scheme 3 Stereochemical Pathways of Nucleopalladation. In the present review, we summarize recent progress in two synergistic areas: (1) mechanistic studies of the stereochemical pathway of nucleopalladation reactions of alkenes (i.e., cis- vs. trans-nucleopalladation) under catalytically relevant reaction conditions and (2) advances in the development of enantioselective Pd-catalyzed reactions that proceed via nucleopalladation of an alkene substrate. The results summarized in the first portion of this review highlight the mechanistic complexity of these reactions and illustrate how subtle changes to the catalyst, substrate, and/or the reaction conditions can alter the stereochemical course of the reaction. Despite the challenges associated with enantioselective PdII-catalyzed reactions of alkenes, important progress has been made over the past 10–15 years. These advances are surveyed in the second portion of this review. The comprehensive coverage of this review begins with results from the late 1990s and early 2000s, when several important advances were made, including the first examples of highly enantioselective reactions proceeding via nucleopalladation6,7,8,9 and the development of ligand-supported Pd-catalysts for aerobic Wacker-type cyclization reactions.10,11 It is hoped that the collective presentation of mechanistic insights and empirical reaction-discovery efforts in this review will provide a foundation for accelerated progress in this important field.

Formic-acid-induced depolymerization of oxidized lignin to aromatics

Abstract: Lignin is a heterogeneous aromatic biopolymer that accounts for nearly 30% of the organic carbon on Earth and is one of the few renewable sources of aromatic chemicals. As the most recalcitrant of the three components of lignocellulosic biomass (cellulose, hemicellulose and lignin), lignin has been treated as a waste product in the pulp and paper industry, where it is burned to supply energy and recover pulping chemicals in the operation of paper mills. Extraction of higher value from lignin is increasingly recognized as being crucial to the economic viability of integrated biorefineries. Depolymerization is an important starting point for many lignin valorization strategies, because it could generate valuable aromatic chemicals and/or provide a source of low-molecular-mass feedstocks suitable for downstream processing. Commercial precedents show that certain types of lignin (lignosulphonates) may be converted into vanillin and other marketable products, but new technologies are needed to enhance the lignin value chain. The complex, irregular structure of lignin complicates chemical conversion efforts, and known depolymerization methods typically afford ill-defined products in low yields (that is, less than 10-20wt%). Here we describe a method for the depolymerization of oxidized lignin under mild conditions in aqueous formic acid that results in more than 60wt% yield of low-molecular-mass aromatics. We present the discovery of this facile C-O cleavage method, its application to aspen lignin depolymerization, and mechanistic insights into the reaction. The broader implications of these results for lignin conversion and biomass refining are also considered.

Overcoming the "oxidant problem": strategies to use O2 as the oxidant in organometallic C-H oxidation reactions catalyzed by Pd (and Cu).

Abstract: Oxidation reactions are key transformations in organic chemistry because they can increase chemical complexity and incorporate heteroatom substituents into carbon-based molecules. This principle is manifested in the conversion of petrochemical feedstocks into commodity chemicals and in the synthesis of fine chemicals, pharmaceuticals, and other complex organic molecules. The utility and function of these molecules correlate directly with the presence and specific placement of oxygen and nitrogen heteroatoms and other functional groups within the molecules.Methods for selective oxidation of C–H bonds have expanded significantly over the past decade, and their role in the synthesis of organic chemicals will continue to increase. Our group’s contributions to this field are linked to our broader interest in the development and mechanistic understanding of aerobic oxidation reactions. Molecular oxygen (O2) is the ideal oxidant. Its low cost and lack of toxic byproducts make it a highly appealing reagent that c...

“Bioinformatics” 특집을 내면서

Abstract: BIOE 402. Medical Technology Assessment. 2 or 3 hours. Bioentrepreneur course. Assessment of medical technology in the context of commercialization. Objectives, competition, market share, funding, pricing, manufacturing, growth, and intellectual property; many issues unique to biomedical products. Course Information: 2 undergraduate hours. 3 graduate hours. Prerequisite(s): Junior standing or above and consent of the instructor.

Benchmarking Heterogeneous Electrocatalysts for the Oxygen Evolution Reaction

Abstract: Objective evaluation of the activity of electrocatalysts for water oxidation is of fundamental importance for the development of promising energy conversion technologies including integrated solar water-splitting devices, water electrolyzers, and Li-air batteries. However, current methods employed to evaluate oxygen-evolving catalysts are not standardized, making it difficult to compare the activity and stability of these materials. We report a protocol for evaluating the activity, stability, and Faradaic efficiency of electrodeposited oxygen-evolving electrocatalysts. In particular, we focus on methods for determining electrochemically active surface area and measuring electrocatalytic activity and stability under conditions relevant to an integrated solar water-splitting device. Our primary figure of merit is the overpotential required to achieve a current density of 10 mA cm–2 per geometric area, approximately the current density expected for a 10% efficient solar-to-fuels conversion device. Utilizing ...

Electrocatalysis for the oxygen evolution reaction: recent development and future perspectives

Abstract: There is still an ongoing effort to search for sustainable, clean and highly efficient energy generation to satisfy the energy needs of modern society. Among various advanced technologies, electrocatalysis for the oxygen evolution reaction (OER) plays a key role and numerous new electrocatalysts have been developed to improve the efficiency of gas evolution. Along the way, enormous effort has been devoted to finding high-performance electrocatalysts, which has also stimulated the invention of new techniques to investigate the properties of materials or the fundamental mechanism of the OER. This accumulated knowledge not only establishes the foundation of the mechanism of the OER, but also points out the important criteria for a good electrocatalyst based on a variety of studies. Even though it may be difficult to include all cases, the aim of this review is to inspect the current progress and offer a comprehensive insight toward the OER. This review begins with examining the theoretical principles of electrode kinetics and some measurement criteria for achieving a fair evaluation among the catalysts. The second part of this review acquaints some materials for performing OER activity, in which the metal oxide materials build the basis of OER mechanism while non-oxide materials exhibit greatly promising performance toward overall water-splitting. Attention of this review is also paid to in situ approaches to electrocatalytic behavior during OER, and this information is crucial and can provide efficient strategies to design perfect electrocatalysts for OER. Finally, the OER mechanism from the perspective of both recent experimental and theoretical investigations is discussed, as well as probable strategies for improving OER performance with regards to future developments.

Palladium(II)-catalyzed C-H activation/C-C cross-coupling reactions: versatility and practicality.

Abstract: Pick your Pd partners: A number of catalytic systems have been developed for palladium-catalyzed CH activation/CC bond formation. Recent studies concerning the palladium(II)-catalyzed coupling of CH bonds with organometallic reagents through a PdII/Pd0 catalytic cycle are discussed (see scheme), and the versatility and practicality of this new mode of catalysis are presented. Unaddressed questions and the potential for development in the field are also addressed. In the past decade, palladium-catalyzed CH activation/CC bond-forming reactions have emerged as promising new catalytic transformations; however, development in this field is still at an early stage compared to the state of the art in cross-coupling reactions using aryl and alkyl halides. This Review begins with a brief introduction of four extensively investigated modes of catalysis for forming CC bonds from CH bonds: PdII/Pd0, PdII/PdIV, Pd0/PdII/PdIV, and Pd0/PdII catalysis. A more detailed discussion is then directed towards the recent development of palladium(II)-catalyzed coupling of CH bonds with organometallic reagents through a PdII/Pd0 catalytic cycle. Despite the progress made to date, improving the versatility and practicality of this new reaction remains a tremendous challenge.

Chemical Redox Agents for Organometallic Chemistry

Abstract: 1. Advantages of Chemical Redox Agents 878 2. Disadvantages of Chemical Redox Agents 879 C. Potentials in Nonaqueous Solvents 879 D. Reversible vs Irreversible ET Reagents 879 E. Categorization of Reagent Strength 881 II. Oxidants 881 A. Inorganic 881 1. Metal and Metal Complex Oxidants 881 2. Main Group Oxidants 887 B. Organic 891 1. Radical Cations 891 2. Carbocations 893 3. Cyanocarbons and Related Electron-Rich Compounds 894