Nanoporous carbon (NPC) is a purely graphitic material with highly controlled densities ranging from less than 0.1 to 2.0 g/cm3, grown via pulsed-laser deposition. Decreasing the density of NPC increases the interplanar spacing between graphene-sheet fragments. This ability to tune the interplanar spacing makes NPC an ideal model system to study the behavior of carbon electrodes in electrochemical capacitors and batteries. We examine the capacitance of NPC films in alkaline and acidic electrolytes, and measure specific capacitances as high as 242 F/g.
Electrochemical capacitors based on redox-active metal oxides show great promise for many energy-storage applications. These materials store charge through both electric double-layer charging and faradaic reactions in the oxide. The dimensions of the oxide nanomaterials have a strong influence on the performance of such capacitors. Not just due to surface area effects, which influence the double-layer capacitance, but also through bulk electrical and ionic conductivities. Ni(OH)2 is a prime candidate for such applications, due to low cost and high theoretical capacity. We have examined the relationship between diameter and capacity for Ni/Ni(OH)2 nanorods. Specific capacitances of up to 511 F/g of Ni were recorded in 47 nm diameter Ni(OH)2 nanorods.
Nanoporous carbon (NPC) is a purely graphitic material with highly controlled densities ranging from less than 0.1 to 2.0 g/cm3, grown via pulsed-laser deposition. Decreasing the density of NPC increases the interplanar spacing between graphene-sheet fragments. This ability to tune the interplanar spacing makes NPC an ideal model system to study the behavior of carbon electrodes in electrochemical capacitors and batteries. We examine the capacitance of NPC films in alkaline and acidic electrolytes, and measure specific capacitances as high as 242 F/g.
A molecular-scale interpretation of interfacial processes is often downplayed in the analysis of traditional water treatment methods. However, such an approach is critical for the development of enhanced performance in traditional desalination and water treatments. Water confined between surfaces, within channels, or in pores is ubiquitous in technology and nature. Its physical and chemical properties in such environments are unpredictably different from bulk water. As a result, advances in water desalination and purification methods may be accomplished through an improved analysis of water behavior in these challenging environments using state-of-the-art microscopy, spectroscopy, experimental, and computational methods.
Here, self-assembled monolayers (SAMS) have been investigated for their ability to confine the absorption of the motor protein kinesin and direct the movement of microtubule shuttles (MTs) within channels of a lithographically patterned microfluidic device. Channels were made from gold films deposited on a silicon wafer to provide chemically distinct surfaces for the selective formation of a range of alkane thiol monolayers on channel walls. Devices were then exposed to solutions containing casein and kinesin to develop protein monolayers capable of propelling microtubules in the presence of adenosine triphosphate (ATP) fuel. Fluorescence microscopy images were used to observe the attachment of MTs to chemically distinct regions and to evaluate the ability of the various monolayer coatings to confine the movement of MTs within the channel system. Ellipsometry was used to characterize the protein adsorption characteristics of SAMS terminated with different functional groups to help establish confinement mechanisms. Finally, both anti-fouling and cationic monolayers were found to be effective in confining MT movement within the channels by controlling the adsorption or orientation of the casein buffer layers that mediate motor protein attachment and functionality.