Award Data

The DoD faces mounting costs for integrated circuits built with advanced technology. Our proposal addresses mixed-signal ASIC design costs and fabrication costs, notably photomask costs and photolithography costs. The ADONIS 1D design methodology has been demonstrated at technologies ranging from 130nm to 16nm. In Phase I of the program, we used ADONIS to design a reference circuit a high-speed c ...

Cost-effective application of advanced commercial electronics technologies in DoD space systems requires early development of radiation-hardened-by-design (RHBD) techniques, and use of simulations is critical to the efficiency of this process. CFDRC has developed an integrated, mixed-mode simulation approach allowing their NanoTCAD device physics simulator to interface with commercial circuit simu ...

Compact Electromagnetic Pulse Module (EMP) capable of being arranged in series-parallel planar or cylindrical arrays is needed to simulate nuclear weapon effects. High gain optically triggered photoconductive semiconductor switches (PCSS) based on Gallium arsenide (GaAs) with low timing jitter enables the development of planar or phased arrays of modular EMP or High Power Microwave (HPM) sources. ...

For applications in DoD satellite systems, devices based on novel nanomaterials offer significant advantages over traditional technologies in terms of light-weight and efficiency. Examples of such novel devices include quantum dot (QD) based solar cells, photodetectors, radars and sensors. However, the response of these devices to radiation effects is not well understood, and radiation effects mod ...

Future high-performance integrated circuits in DoD satellite systems will require non-planar nano-technology devices, such as MultiGate Field Effect Transistors (MuGFET) or FinFET, which can decrease pattern area of logic circuits below 50% of the conventional planar technologies. The International Technology Roadmap for Semiconductors predicts that such devices will be the cornerstone of sub-32nm ...

The use of WMDs and IEDs by covert insurgents and terrorists poses a significant risk to U.S. military forces and civilians. The capability to execute rapid forensic DNA analysis to identify individuals who manufactured and transported these threatening devices is of paramount importance to military mission, homeland security and civilian safety. Current DNA forensic analyses are time-consuming, b ...

Sample preparation has been recognized as the single most important challenge to be faced in the development of detect-to-warn (DTW) systems. Available commercial sample preparation technologies are expensive, slow, and require trained laboratory technicians and sophisticated laboratory equipment for operation. Addressing this need, we propose to design, fabricate, and demonstrate a general purpos ...

With the current state of world events, the threat of explosives used against high-value targets is more pronounced than ever before. As a result, simulation of blast events and their effects on structures has become an increasingly vital capability. Current blast simulations on Central Processing Units (CPU) resources require a significant amount of computational time, limiting their overall valu ...

Current offensive solutions to neutralize chem/bio agent facilities rely on blast and/or short-burst high-temperature neutralization but have the potential to produce severe collateral damage via agent release. Our team proposes the Dispersed Energetics Coupled for Optimized Neutralization (DECON) Concept, an alternative concept to perform bulk neutralization of agents. The DECON concept can be s ...

Electronic equipment, especially communication equipment, is extremely vulnerable to various forms of electromagnetic radiation whether natural or man-made due to minimal shielding and high sensitivity to radio waves. An ideal transient hardening device would limit the harmful energy as it enters the circuitry by minimizing the over-voltage. It would have to respond very fast and be able to handl ...