NOVEL DESIGN OF FUNCTIONALIZED CARBON NANOTUBE ELECTRODES AND MEMBRANES FOR FUEL CELLS AND ENERGY STORAGE

Su, Xin

01 January 2012

A novel electrochemical method to generate nm-scale bubbles at the tips of CNTs can temporarily block the membrane. A 92% blocking efficiency is achieved when the bubbles are stabilized in 30-60 nm diameter „wells‟ at the tips of CNTs. This well is formed by the electrochemical oxidation of the conductive CNTs partially into the polymer matrix of the membrane. Meanwhile, the nanoscale bubbles can be removed with 0.004 atm pressure to recover the transport through the CNT membrane. The CNT membrane with nanoscale bubble valve system was used to demonstrate electrochemical energy storage. Uniform ultrathin Pt films were electrodeposited onto an aligned array of carbon nanotubes (CNTs) for high-area chemically stable methanol fuel cell anodes. Electrochemical treatment of the graphitic CNT surfaces by diazonium benzoic acid allowed for uniform Pt electroplating. The mass activity of the Pt thin film can reach 400 A/g at a scan rate of 20 mV/s and in a solution of 1 M CH3OH/0.5 M H2SO4. A novel programmed pulse potential at 0 V was also seen to nearly eliminate the effects of carbon monoxide poisoning on catalyst Pt. Furthermore, the Pt monolayer was deposited on buckypaper by replacing the precursor Cu monolayer coated on CNTs by the underpotential deposition. The electrochemical surface modification of graphite CNTs by fluorinated benzoic acid was critical to coordinate Cu ions for monolayer formation. The mass activity of the monolayer can be improved to the record value of 2711 A/g. This is about 13 times higher than that of the ~10 nm thick Pt film coated on MWCNTs. Besides the high mass activity, the Pt monolayer coated on buckypaper can be used as catalyst for fuel cells with several advantages such as low cost, high surface area, flexibility, mechanical robustness and enhanced pressure flow. Finally, a new strategy has been developed toward electrochemical water oxidation with Ir complexes catalyst, which was grafted on buckypaper by direct binding to enhance catalyst activity. The TOF (turn over frequency) of the Ir catalyst for water splitting was 7.9 s-1 at the constant potential of 1.4 V vs Ag/AgCl.

Pt

monolayer

fuel cell

CNT membrane

energy storage

Engineering

Materials Science and Engineering

Nanoscience and Nanotechnology

CNT MEMBRANE PLATFORMS FOR TRANSDERMAL DRUG DELIVERY AND APTAMER MODULATED TRANSPORT

Chen, Tao

01 January 2014

CNT membrane platforms are biomimetic polymeric membranes imbedded with carbon nanotubes which show fast fluid flow, electric conductivity, and the ability to be grafted with chemistry. A novel micro-dialysis probe nicotine concentration sampling technique was proposed and proved in vitro, which could greatly improve the efficiency and accuracy of future animal transdermal studies. To enhance the scope of transdermal drug delivery which was limited to passive diffusion of small, potent lipophilic drugs, a wire mesh lateral electroporation design was also proposed which could periodically disrupt the skin barrier and enhance drug flux. It was shown that AMP binding aptamer at the tip of carbon nanotubes may act as gatekeepers and regulate ionic transport through CNT membrane. Multiple cycle gating of ionic transport upon AMP binding/unbinding which changes the aptamer conformation was displayed. This CNT membrane-aptamer system closely mimics how protein ion channels modulate ion flow by responding to stimuli, which may have significant impact on active membrane transport. Finally an enhanced electroosmosis concept by “ratchet” functionalization at both ends of carbon nanotubes in was discussed. Direct observation of water transport by electroosmosis was made possible through enhanced flow in vertically aligned high flux CNT membranes.

CNT membrane

transdermal drug delivery

electroporation

aptamer

electroosmosis

Biology and Biomimetic Materials

Nanoscience and Nanotechnology

Other Materials Science and Engineering