33 research outputs found
Polymer composites for energy storage and conversion
Since their discovery, conductive polymers have been studied extensively because of their fascinating physics and broad potential in technological applications. In this seminar, I will describe our use of doped conducting polymers as materials in energy-related technologies. Conductive polymers can be synthesized via chemical or electrochemical oxidation, producing a polycationic material that requires charge-compensating dopants. A variety of anionic dopants have been used including Cl-, ClO4-, BF4-, p-toluenesulfonate, dodecylbenzenesulfonate (DBS), and polystyrenesulfonate (pSS), all of which function to balance the cationic charge of the conductive polymer. More recently, our lab and others have introduced other dopants, which in addition to balancing the charge of the polymer, possess a distinct characteristic that imparts a new property or function to the composite. For example, proteins and peptide dopants impart bioactivity, whereas carbon nanotubes and hydrogen-bonding dopants enhance mechanical strength. Redox-active dopants improve electron transfer between the cathode of a biofuel cell to the active site of enzymes embedded in the conductive matrix, improve the energy density of batteries made from conductive polymers, yield a light-harvesting material, and add new colored states in electrochromic films. The performance of several devices made from conducting polymers will be presented
Lipoproteins and Diseases of the Brain
Apolipoprotein E4 (apoE4) and outer surface protein A (ospA) are pathogenic lipoproteins involved in the progression of Alzheimer’s disease and Lyme neuroborreliosis, respectively. Results from previous studies indicate that apoE4 exhibits neurotoxicity by activating amyloid beta pathways, and ospA causes damage to the brain by stimulating immune activity of microglia and astrocytes. These results, however, lack information about the specific interactions that develop between neurons and these two lipoproteins. It is essential to investigate the effect of these lipoproteins on neuronal morphology and function to better understand the mechanism of damage and disease of the brain. This chapter summarizes previous studies on the role of apoE4 and ospA in diseases of the brain and discusses experimental results from our own work that suggests new roles for apoE4 and ospA in neuronal outgrowth and synaptic loss
A scalable method for preparing Cu electrocatalysts that convert CO2 into C2+ products
Selective reduction of carbon dioxide to high-value products is key for advancing carbon capture and utilization technologies. Here the authors prepare a copper catalyst for electrocatalytic conversion of carbon dioxide to C2+ products with enhanced selectivity that is attributed to a high density of surface defects
Synthesis, Crystal Structure, and Electrochemical Properties of Alluaudite Na<sub>1.702</sub>Fe<sub>3</sub>(PO<sub>4</sub>)<sub>3</sub> as a Sodium-Ion Battery Cathode
Sodium-ion
batteries hold promise as an enabling technology for
large-scale energy storage that is safer, less expensive, and lower
environmentally impactful than their equivalent lithium-ion batteries.
Reported herein is the one-pot hydrothermal synthesis, crystal structure,
and electrochemical properties of a promising sodium-ion battery cathode
material, an alluaudite phase of Na<sub>1.702</sub>Fe<sub>3</sub>(PO<sub>4</sub>)<sub>3</sub>. After ball milling and carbon coating, this
material exhibits a reversible capacity of ∼140 mAh/g with
good cycling performance (93% of the initial capacity is retained
after 50 cycles) and excellent rate capability. This alluaudite compound
and its method of preparation is a promising cathode for large-scale
battery applications that are earth-abundant and sustainable