NanoTechnology: Materials, Processes & Devices

We have developed a new, ultra-sensitive and affordable 3D scanner designed to image the distribution of a magnetic nanostructure contrast agents in vivo. MPI has several important advantages over existing imaging methods, such as MRI, ultrasound, nuclear medicine, and CT. First, the Magnetic Particle Imaging scanner directly detects a nanoparticle's electronic magnetism, which is 1 million times more intense than the nuclear paramagnetism detected in MRI, so this new modality promises unprecedented contrast-to-noise ratio (CNR). MPI employs MRI nanoparticle contrast agents, which...

Due to tightened regulations on environmental control and high demand on clean fuel, there is great interest in developing a method whose process and product are both eco-friendly. Hydrogen is a fuel of high quality and zero emission. Hydrogen can be directly produced by splitting water into H2 and O2. This project focuses on photochemical splitting of water using solar energy and InP as the photocatalyst. In an effort to enhance the efficiency, the InP is textured to have very low reflectivity.

Project end date: 08/19/11

Current methods of growing nanostructures use bulk fabrication processes. Examining new methods to focus where and how these structures are synthesized will allow more complex devices to be made. Lasers can act as an energy source that locally heats material. By concentrating lasers on specific thin films during processing, nanostructures can be grown over small areas with greater precision. This process will also provide a means to grow very different structures within close proximity to each other. Finally, the amount of heat transferred to the films can be fine-tuned with the...

We demonstrate ultrathin body (UTB) high mobility InAsSb-on-insulator (XOI) n-FETs. The devices are obtained by the epitaxial layer transfer (ELT) of ultrathin InAsSb layers (thickness, 7-17 nm) onto Si/SiO2 substrates. InAsSb XOI FETs exhibit a peak effective mobility of ~5000 cm2/V-s and an ION/IOFF ratio of over 104. The top-gated devices exhibit an impressive ION of ~0.24 mA/micron (LG~500 nm) at VDD=0.5 V and a SS of ~109 mV/dec. These results demonstrate the utility of the XOI platform for obtaining high mobility n-FETs on Si by using mixed anion arsenide-antimonide as the...