Chemistry Guest Seminars

A&P + Inorganic Seminar

Thursday, September 24, 3:30 - 4:30pm, ZOOM

Elucidating Proton-Coupled Electron Transfer Mechanisms Underpinning the Catalytic Generation of Renewable Fuels

Jillian L. Dempsey

Associate Professor

University of North Carolina Chapel Hill

Dempsey Group

Abstract:  The conversion of energy-poor feedstocks like water and carbon dioxide into energy-rich fuels involves multi-electron, multi-proton transformations. In order to develop catalysts that can mediate fuel production with optimum energy efficiency, this complex proton-electron reactivity must be carefully considered. Using a combination of electrochemical methods and time-resolved spectroscopy, we have revealed new details of how molecular catalysts mediate the reduction of protons to dihydrogen and the experimental parameters that dictate catalyst kinetics and mechanism. Through these studies, we are revealing opportunities to promote, control and modulate the proton-coupled electron transfer reaction pathways of catalysts.

Publications (Group Page)

Author Metrics

h-index: 28  Total Articles: 57  Total Citations: 3143  (Web of Science, Sep. 2020)

Thursday, August 20, 3:30 - 4:30pm, ZOOM

Panoptic Mass Spectrometry: How and Why

Abraham Badu-Tawiah

Associate Professor

Ohio State University

Badu Group

Recent innovation in mass spectrometry (MS) is the ability to generate intact molecular ions, focus and use them as ordinary reagents for organic reactions at ambient surface, outside the mass spectrometer. Most projects in the Badu lab build on this innovation, but instead of simple organic compounds, we focus on drugs and biomolecules of specific biological importance.  For example, selected proteins and antibodies can be aerosolized, and the resulting molecular cations/anions are directed onto a surface (paper, glass, tissue sections, etc.) for specific molecular recognition. Such experiments are expected to allow rapid and sensitive detection of drugs, tumor markers and antigens of infectious diseases. We are designing novel molecular probes for ambient MS analysis and imaging of proteins, antibodies, antigens, nucleic acids, and other disease biomarkers. The probes are rationally designed to facilitate (1) point-of-care and direct-to-customer applications with handheld mass spectrometers, and (2) a novel on-demand disease diagnostic concept that permits onsite friendly sample collection followed by analysis at a later time without affecting diagnostic outcome. Major efforts in our lab are also dedicated to the introduction of charged aerosols for treating respiratory diseases. This research has potential to advance our current understanding in aerosol therapy, and may yield new focus for general drug synthesis in which molecular ions, instead of their neutral counterparts, are used in medicine.

Publications (Group Page)

Publications (Google Scholar Citations)

ORCID:  https://orcid.org/0000-0001-8642-3431

Author Metrics

h-index: 19  Total Articles: 44  Total Citations: 1048  (Web of Science, Aug. 2020)

h-index: 21  Total Citations: 1405  (Google Scholar Citations, Aug. 2020)

Thursday, May 14, 3:30 - 4:30pm, ZOOM

Pushing the boundaries of H/D exchange-mass spectrometry to analyze glycans

Elyssia S. Gallagher

Assistant Professor

Baylor University

Gallagher Group

Abstract:  Glycans are complex molecules with different carbohydrate subunits, linkage stereochemistries, and branching patterns; all of which play a role in their biological functions. Hydrogen / deuterium exchange–mass spectrometry (HDX-MS) has become a standard method for analyzing conformations and binding interactions of solvated proteins. Carbohydrates, model systems for glycans, are susceptible to HDX since they contain labile hydrogens, primarily in the form of hydroxyls, which can be labeled with deuterium (D) upon exposure to deuterated solvents. However, compared to backbone amides, the functional group detected in traditional HDX-MS experiments for proteins, the exchange rate of glycan hydroxyls is two to eight orders of magnitude faster, depending on solution pH. This rapid exchange rate makes it unfeasible to monitor HDX of carbohydrate hydroxyls using traditional, bottom-up HDX methods.  Herein, we describe our ongoing efforts to characterize solvated carbohydrates. We perform rapid HDX by introducing deuterating reagents (e.g. D2O) to carbohydrates during electrospray ionization (ESI). Our work illustrates that these rapid, in-ESI HDX methods characterize solvated carbohydrates rather than gas-phase structures. Furthermore, we have coupled our experimental work with molecular dynamics simulations to identify the mechanism of carbohydrate ionization during ESI. Experimentally, we have quantified how ESI source conditions alter the magnitude of HDX for carbohydrate model systems, developed an internal standard to control for daily humidity differences, and established methods to alter the HDX labeling time on the microsecond to millisecond timescale. We are now applying these in-ESI HDX methods to characterize carbohydrate isomers.

Publications (Group Page)

Publications (Google Scholar Citations)

ORCID:  https://orcid.org/0000-0002-5411-7285

Author Metrics

h-index: 6  Total Articles: 20  Total Citations: 99 (Web of Science, Apr. 2020)

h-index: 8  Total Citations: 149  (Google Scholar Citations, Apr. 2020)

Thursday, March 5, 3:30 - 4:30pm, WEL 2.122

Activation Energies and Beyond

Ward H. Thompson

Professor

University of Kansas

Thompson Group

Abstract:  How the properties of molecular systems change with temperature is one of the most fundamental issues in chemistry. Knowledge of this behavior has not only practical implications, but fundamental ones, as it permits the separation of energetic and entropic driving forces.  In this talk, recent advances in the calculation and interpretation of the activation energy for a dynamical process will be discussed. Specifically, new approaches that enable the direct determination of the activation energy for any timescale from simulations at a single temperature will be presented. These methods open up significant new possibilities for understanding dynamics from diffusion to reorientation to chemical reaction in cases where a traditional Arrhenius analysis is not possible or applicable. They also enable otherwise unavailable mechanistic insight via a rigorous decomposition of the activation energy into contributions associated with the different interactions (e.g., Coulombic, Lennard-Jones) and motions present in the system.  The approach is illustrated by application to the diffusive and reorientational dynamics of water under ambient and supercooled conditions.

Publications (Group Page)

Publications (Google Scholar Citations)

ORCID:  https://orcid.org/0000-0002-3636-6448

Author Metrics

h-index: 34  Total Articles: 127  Total Citations: 3503 (Web of Science, Feb. 2020)

h-index: 29  Total Citations: 2465  (Google Scholar Citations, Feb. 2020)

A&P and Inorganic Seminar

Monday, February 24, 3:30pm - 4:30pm, WEL 2.122

Water Dissociation Catalysis

Shannon Boettcher

Associate Professor

University of Oregon

Boettcher Lab

Abstract:  Water is arguably the most-important molecule to humanity due to its ubiquitous role in biological, industrial, and environmental processes. Reactions of water typically involve breaking the H-O bond. The simplest reaction is heterolytic water dissociation (WD), H2O -> H+ + OH-, the understanding of which has been a focal point of experiment and theory for decades. Related dissociative adsorption reactions occur on surfaces and are important when water is used as a reactant for thermochemical processes, such as the water-gas-shift reaction. In biological systems, metalloenzymes such as carbonic anhydrase dissociate water to catalyze, for example, CO2 equilibria. WD is further a fundamental elementary step in many electrochemical processes. For example, the WD step is thought to be rate-limiting for the hydrogen evolution reaction (HER) under alkaline conditions and thus modification Pt HER catalysts with metal hydroxides, that presumably accelerate WD, lead to large increases in HER activity. While measurements of dissociative water adsorption are often made using the tools of surface science under vacuum conditions, the WD reaction has not been systematically studied under electrochemical conditions. We use a bipolar-membrane (BPM) electrolyzer (where WD is driven in the region between a hydroxide-exchange membrane and a proton-exchange membrane by an applied potential) to study WD kinetics across a range of materials. We find that the local pH is a critical, but previously unrecognized, variable affecting WD kinetics and a pH dependent proton transfer WD mechanism is proposed. Combining WD catalysts efficient in locally acidic conditions with those efficient in basic conditions, nearly eliminates the WD overpotential in BPM electrolyzers operating at 20 mA cm-2. The catalysts enable continuous BPM operation at 0.5 A cm-2 with a total applied electrolysis potential of ~ 2 V – substantial improvements over the state of the art and suggesting new applications for BPMs. We further discovered that the WD kinetics measured in the BPM correlate with HER kinetics under conditions where WD is an important elementary step. We discuss the design of bifunctional electrocatalysts based on the insight into the underlying WD steps.

Publications (Group Page)

Publications (Google Scholar Citations)

ORCID:  https://orcid.org/0000-0001-8971-9123

Author Metrics

h-index: 43  Total Articles: 109  Total Citations: 16,278  (Web of Science, Jan. 2020)

h-index: 45  Total Citations: 18,667  (Google Scholar Citations, Jan. 2020)

Thursday, February 20, 3:30pm - 4:30pm, WEL 2.122

Local to Global: Perspectives on Electrochemistry at Carbon Electrodes

Patrick Unwin

Professor

University of Warwick

Warwick Electrochemistry & Interfaces

Abstract: With a focus on sp² carbon materials – graphite, graphene and single walled carbon nanotubes (SWNTs) – and conducting diamond, this lecture will discuss recent advances in carbon electrochemistry and the process of challenging ‘conventional thinking’. Carbon materials have long been used as electrodes in electrochemistry, with applications from (bio)electroanalysis to energy technologies, such as batteries and fuel cells. With the advent of new forms of nano-carbon, carbon electrode materials have taken on even greater significance in electrochemistry. Textbook models for the response of carbon electrode materials have emphasized the importance of surface defects as active sites, even for simple redox processes. We have pioneered new electrochemical imaging techniques to test these models and examine the intrinsic electrochemical activity of carbon materials directly and with unprecedented detail and spatial resolution. When high resolution electrochemical imaging data are combined with information from other microscopy and spectroscopy techniques applied to the same area of an electrode surface, in a correlative-electrochemical microscopy approach, highly resolved and unambiguous pictures of electrode activity are revealed. These new views of the electrochemical properties of carbon materials are consistent over a wide range of length scales and time scales, and allow the rational design of next generation carbon electrode surfaces.

Publications (Group Page)

Publications (Google Scholar Citations)

Author Metrics

h-index: 61  Total Articles: 357  Total Citations: 14,075  (Web of Science, Feb. 2020)

h-index: 71  Total Citations: 19,302  (Google Scholar Citations, Feb. 2020)

Thursday, February 13, 3:30pm - 4:30pm, WEL 2.122

Combining mass spectrometry and nanodiscs to investigate membrane protein-lipid interactions

Michael T. Marty

Assistant Professor

University of Arizona

Marty Lab

Abstract:  Due to their important biochemical roles, membrane proteins are important drug targets. Although it is clear that lipids can influence membrane protein function, the chemistry of lipid binding remains difficult to study because protein-lipid interactions are polydisperse, competitive, and transient. Furthermore, detergents, which are often used to solubilize membrane proteins, may disrupt lipid interactions that occur in lipid bilayers. We have been developing new approaches to quantify protein-lipid interactions in bilayers and understand how membrane proteins remodel their surrounding lipid environment. In one new approach, we use mass spectrometry (MS) to quantify the exchange of lipids between lipoprotein nanodiscs with and without an embedded membrane protein. Shifts in the lipid distribution towards the membrane protein nanodiscs reveal lipid binding, and titrations allow measurement of the optimal lipid composition for the membrane protein. Second, we use native MS to ionize membrane protein nanodiscs with heterogeneous lipids. Ejecting the membrane protein complex with bound lipids in the mass spectrometer revealed enrichment of specific lipids around the membrane protein. Ultimately, we expect these unique combinations of nanodiscs and MS will provide new insights into the chemistry and selectivity of membrane protein-lipid interactions.

Publications (Group Page)

Publications (Google Scholar Citations)

ORCID:  https://orcid.org/0000-0001-8115-1772

Author Metrics

h-index: 16  Total Articles: 34  Total Citations: 809 (Web of Science, Jan. 2020)

h-index: 15  Total Citations: 835  (Google Scholar Citations, Jan. 2020)