8 research outputs found
Report of microstructural analysis of PEM failures
Issued as Final report, Project E-18-X29Final report has author: W. Jud Read
Ultra Strong Silicon-Coated Carbon Nanotube Nonwoven Fabric as a Multifunctional Lithium-Ion Battery Anode
Materials that can perform simultaneous functions allow for reductions in the total system mass and volume. Developing technologies to produce flexible batteries with good performance in combination with high specific strength is strongly desired for weight- and power-sensitive applications such as unmanned or aerospace vehicles, high-performance ground vehicles, robotics, and smart textiles. State of the art battery electrode fabrication techniques are not conducive to the development of multifunctional materials due to their inherently low strength and conductivities. Here, we present a scalable method utilizing carbon nanotube (CNT) nonwoven fabric-based technology to develop flexible, electrochemically stable (∼494 mAh·g<sup>–1</sup> for 150 cycles) battery anodes that can be produced on an industrial scale and demonstrate specific strength higher than that of titanium, copper, and even a structural steel. Similar methods can be utilized for the formation of various cathode and anode composites with tunable strength and energy and power densities
A thin film triode type carbon nanotube field emission cathode
The field electron emission of carbon nanotubes has been heavily studied over the past
two decades for various applications, such as in display technologies, microwave amplifiers, and
spacecraft propulsion. However, a commercializable lightweight and internally gated electron
source has yet to be realized. This work presents the fabrication and testing of a novel internally
gated carbon nanotube field electron emitter. Several specific methods are used to prevent
electrical shorting of the gate layer, a common failure for internally gated devices. A unique design
is explored where the etch pits extend into the Si substrate and isotropic etching is used to create a
lateral buffer zone between the gate and carbon nanotubes. Carbon nanotubes are self-aligned to
and within 10 microns from the gate, which creates large electric fields at low potential inputs.
Initial tests confirm high field emission performance with an anode current density (based on total
area of the device) of 293 μA cm-2 and a gate current density of 1.68 mA cm-2 at 250 V