Award Data

The objective of this Phase I project is to evaluate the use of novel Laser Induced Surface Improvement (LISI) techniques to provide surface modification to substrate materials which will provide superior wear resistance in extreme conditions. The specific application of interest is the hypersonic metal-to-metal contact that occurs at high speed test track facilities that can and has lead to catas ...

Using its novel carbon nanosheet technology, Luna Innovations will develop a Supercapacitor with the highest energy densities available in the microsecond to millisecond response times. Nanosheets are vertically aligned graphene sheets that can be grown on a wide variety of substrates without catalyst and have an open, accessible surface area that eliminate the resistance due to pores that cause ...

The growing complexity of future military systems demands the development of high-performance nonlinear control algorithms. The goal of this proposal is to develop a specially designed software/hardware architecture to enable real-time autonomous closed-loop control of nonlinear high-dimensional dynamical systems. Following the recent success of pseudospectral (PS) computational control methods in ...

The leakage of electromagnetic (EM) energy into air vehicles, and particularly into ordnance, poses a hazard that requires careful evaluation. Under current guidelines, such evaluations are primarily to be carried out through extensive testing of items under possible field conditions, a process that can be both time-consuming and costly. The scope of this STTR Phase I activity is to implement a h ...

The goal of the proposed research is to develop advanced computational tool for high-fidelity simulations of hypersonic non-equilibrium plasmas. Octree adaptive Cartesian mesh will be used for automatic mesh generation and dynamic mesh adaptation to plasma properties, particularly important for hypersonic flows with strong shock waves, transient laminar and turbulent domains with large gradients o ...

A mathematical framework for detection and classification of weak, distributed patterns on computer networks is proposed. The framework will provide rigorous methods for understanding performance bounds and optimality of intrusion detection methods, while also providing concrete and implementable algorithms. The algorithms will find immediate application in cyber-security efforts, as well as mor ...

The proposed effort develops the understanding required to assess the utility of using OAM states and quantum entanglement as a novel protocol for quantum key distribution for propagation through an aberrating medium such as the atmosphere. In addition a conceptual design of an experiment that is appropriate to further the development of this capability will be developed on the proposed Phase I e ...

Combustion stability is an important consideration in the design of liquid rocket engines. While fundamental modes of unstable operation in simple geometries are easily identified using analytical methods, recent times have seen these methods greatly expand in scope, applied in semi-numerical format to increasingly complex geometries and flow situations. Much remains to be explored in understandin ...

Digital electronics is approaching its limits in meeting the demand for increased processing speeds. Photonics, while promising high processing speed, is lacking integration capacity. Plasmonics promises to combine the information capacity of photonics with the integration density of electronics. The team of Luna Innovations, UCLA and Virginia Tech proposes to develop plasmonic logic devices and c ...

The key to making quantum key distribution practical (especially for free-space applications) is to be able to use weak laser pulses (WLP) instead of single photons, while at the same time making sure that any third party wanting to avoid detection and mount an eavesdropping attack is restricted to using beam-splitting rather than photon-number splitting (PNS). In this effort, we propose a novel s ...