Award Data

Laboratory investigations have suggested that acoustically or vibrationally inducing motion in buried targets can aid in improving target detectability through a characteristic response related to differential target motion. This gain is realized by adding an additional degree of freedom, modulation due to motion in the GPR return signal, to use as a discriminating feature. The AKELA team is propo ...

Lithium metal represents the ultimate anode material due to its high energy density (3860 mAh/g), however, dendrite growth during charge has been essentially preventing its wide application in rechargeable batteries. LiBAMA's bi-functional advanced metal anode (AMA) represents the world's first innovation evolved out of numerous failed and on-going efforts with solid electrolytes, lithium protecti ...

Terrorist use of radioactive nuclear materials via nuclear and/or radiological dispersion devices (dirty bombs) is a serious threat. Therefore, it is crucial to detect proliferation of nuclear material. Critical challenges include: (a) high sensitivity detection of signature emissions from radioactive isotopes, and (b) cost-effectiveness for deployment of sensor networks across large storage facil ...

There is an unmet demand for ultra-low-power, ultra-compact and low-cost radios to address emerging sensing and communication needs for military and commercial applications such as IoT/IoE. To overcome the limitations in existing bulky and power hungry radios, we propose a disruptive solution by integration of a nano-scaled THz transceiver, on-chip antenna, and energy harvesting circuits in a form ...

There is a need to develop affordable and specific biosensors to defend against current and future biological threats. Biological methods of detection have been evolved by nature to detect molecules at the micro-scale with flexible specificity and with downstream effectors. Advances in cell-free technology allow for deployment of biosensors on pH-strip-type paper, an affordable, robust, disposable ...

Within this STTR program, Carbonics will partner with USC to commercialize CNTFET based transistor technology that is compatible with wafer-scale monolithic integration process flows whilst offering exceptional performance at mm-Wave frequencies that can outperform incumbent semiconductor high frequency technologies (GaAs, SiGe, RF-CMOS).

In this project, we propose to develop a high-performance carbon nanotube (CNT) based millimeter-wave transistor technology and demonstrate monolithic millimeter-wave integrated circuits (MMICs) based on this technology with improved power efficiency, linearity, noise and dynamic range performance over existing GaAs, SiGe and RF-CMOS technologies. The goal of this topic is to leverage Professor St ...

Vector Atomic will develop precision, ultra-low noise laser control electronics with low cost, size, weight, and power (C-SWaP). The electronics will be designed to broadly support the various laser types of used for quantum technology, which span 369-1550 nm. The C-SWaP and system architecture will support scaling of quantum systems to higher laser counts. The design will also include essential f ...

In this Project OEwaves Inc. in collaboration with the UCLA trapped-ion quantum computing group proposes to develop extended-cavity ultra-stable diode laser systems that have the properties required for quantum computing and metrology. The system will be based on a semiconductor laser locked to a monolithic microcavity (a whispering gallery mode resonator, WGMR [1]) using a self-injection locking ...

This proposal is related to the development of high efficiency ultraviolet (UV) light emitting devices (LEDs) operating at 265 nm and 219 nm, which have the potential to replace conventional mercury lamps for many applications including dinsinfection and water purification. To date, the wall-plug efficiency of commercial LEDs operating at 265 nm is in the range of 2-3%, which has been limited by t ...