Electrochemical Energy Storage through Ligand-Based Charge Manipulation
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Systematic Methods for Learning Complex Mechanisms from Molecular Dynamics Simulations
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Specific Inhibition of Heparanase by Glycopolymers for Cancer and Diabetic Therapeutics
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Specific Inhibition of Heparanase by Glycopolymers for Cancer and Diabetic Therapeutics
Examining the Dynamics of Glucose Regulation
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Jefferson Lecture - Re-imagining the Periodic Table: Sustainable Catalysis for the 21st Century
New Frontiers in Cosmic Carbon
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Approaches to the Treatment of Alzheimer’s Disease: Two Targets; Two Modalities
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Main Group Lewis Acids for Applications in Catalysis and Anion Transport
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Main group Lewis acids for applications in catalysis and anion transport
Proton-Coupled Electron Transfer by Copper-Oxygen Species Relevant to Enzyme Intermediates
Characterization of copper intermediates in enzymes and other catalysts that attack strong C-H bonds is important for unraveling oxidation catalysis mechanisms and, ultimately, designing new, more efficient catalytic systems. New insights into the nature of such intermediates may be obtained through the design, synthesis, and characterization of copper-oxygen complexes. Two key proposed examples contain [CuO2]+ and [CuOH]2+ cores, which have been suggested as possible reactive intermediates in monocopper enzymes such as lytic polysaccharide monooxygenase.