Compare Green Mountain Radio Research Company to Competitors
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Titanova
Titanova Inc. is a St. Charles, MO based company that has received a grant(s) from the Department of Energy's SBIR/STTR program. The abstract(s) for these grant award(s) are provided as well since they provide insights into Titanova Inc.'s business and areas of expertise. This project will develop direct diode laser systems and processes for purpose of cladding coalfired boiler water walls. This development will result in improved clad material properties, a reduction in coal-fired boiler costs, an increase in boiler efficiencies, and the laser-cladding repair of our warfighter's armored and critical support systems. This project will develop portable diode laser cladding systems for purpose of repairing nuclear power plant systems and components. This program will create high skill jobs, extending the life of the nations 104 nuclear power plants, which provides over 20 percent of the current U.S. electricity supply without carbon emissions.
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AMAC International
AMAC International, Inc. is a Newport News, VA based company that has received a grant(s) from the Department of Energy's SBIR/STTR program. The abstract(s) for these grant award(s) are provided as well since they provide insights into AMAC International, Inc.'s business and areas of expertise. This project will use the innovative SQUID-based scanning system to inspect Nb sheets in fast and highly sensitive fashion to detect micro particles and allow for the highest accelerating fields. It will help considerably in reducing the cost of DOE multi million dollar projects and can be used for many other applications in industries for high sensitive inspection of metals. This innovative SQUID-based scanning system is designed to detect defects and Tantalum inclusions in Niobium sheets used in the fabrication of cavities of accelarators. For the first time, it will be possible to inspect Nb=iobium sheets in a fast and highly sensitive way to allow for the highest quality of accelerating fields in cavities used in the acclerators. It will help considerably in reducing the cost of multi million dollar projects and can be used for many other applications in industries that require highly sensitive non destructive inspection of metals. The innovative double-window RF power input coupler technology developed for the ILC project, the fabrication cost savings obtained with the innovative mechanically simplified technologies developed in the project, and the gained reliability and system simplification could be applied to many accelerator projects. The fabrication technologies developed here can also be widely used in RF power, communication and RF products industries The innovative synchrotron radiation adjustable super-bending magnet will be a key and major component of a future high performance electron-ion collider for nuclear physics. The concept and fabrication technique developed here could also be used in accelerators for high energy physics, synchrotron light sources and industry applications and in other magnetic devices.
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Black Laboratories
Black Laboratories, LLC is a Newport News, VA based company that has received a grant(s) from the Department of Energy's SBIR/STTR program. The abstract(s) for these grant award(s) are provided as well since they provide insights into Black Laboratories, LLC's business and areas of expertise. This project will develop acid-free, electro-polishing methods to facilitate environmentally-friendly, production methods of high performance superconducting radio frequency accelerators. This will result in significant cost savings in the areas of particle physics that require high purity, chemically treated surfaces. Advanced, higher performance particle accelerators are needed to explore the frontiers of nuclear physics and to gain more widespread use for industrial sciences. This project will develop technology that will allow these to be produced with great gains in efficiency and major reductions in cost. Superconducting radio frequency accelerators are used to explore the frontiers of particle physics and discover the properties of a new form of matter. Manufacturing costs for large projects will be in the billions of dollars, but this thin film technology will lower these costs to a fraction of current projections.
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ALEM-RMD Joint Venture
ALEM-RMD Joint Venture is a Watertown, MA based company that has received a grant(s) from the Department of Energy's SBIR/STTR program. The abstract(s) for these grant award(s) are provided as well since they provide insights into ALEM-RMD Joint Venture's business and areas of expertise. The project will investigate two promising nuclear detector materials that will have major impact in medical imaging, physics, homeland security, scientific studies as well as commercial applications. The proposed research will investigate two promising nuclear detector materials that will have major impact in medical imaging, physics, homeland security, scientific studies as well as commercial applications.
FAR-TECH
FAR-TECH, Inc. is a San Diego, CA based company that has received a grant(s) from the Department of Energy's SBIR/STTR program. The abstract(s) for these grant award(s) are provided as well since they provide insights into FAR-TECH, Inc.'s business and areas of expertise. This project will develop a feedback tool that provides an enhanced detection and instability feedback control to speed the commercialization of efficient, clean fusion power. This project will develop and test a precision beam instrument to measure time-of-flight and beam xy-tilt. This diagnostic can provide a non-invasive, fundamental beam parameter benefitting most accelerators. This project will develop a tool with real-time capability to solve the critical problem of disruption mitigation on future fusion reactors such as ITER. It will significantly enhance other fusion and high energy density physics projects as well. This project will build and test a linac accelerating structure. The design significantly simplifies the accelerating structure and is thus cost effective. This project will explore the feasibility of using the Archimedes Filter Technology to augment chemical processing of spent nuclear fuel. The augmentation should reduce the cost and environmental impact of recycling nuclear fuel from advanced high temperature gas cooled reactors. The Archimedes Plasma Mass Filter is an innovative, proliferation resistant technology for separating nuclear waste with potentially lower cost and environmental impact than chemical processing. This project will develop a vaporization source that would enable the Filter to be applied to the recycling of commercial spent nuclear fuel. High-power radio frequency (RF) sources are used to power the majority of particle accelerators used research, military, industrial and medical applications. This project will provide a high-efficiency RF source for Thomas Jefferson National Accelerator Laboratory, with the basic technology also usable for many other future projects. This project will develop a sophisticated, numerical modeling tool that will decrease the cost of building and operating sources of highly charged ions that are used in nuclear physics research as well as industrial applications. This project will develop a sophisticated, numerical modeling tool that will decrease the cost of building and operating sources of highly charged ions that are used in nuclear physics research as well as industrial applications. Petascale computing, will eventually impact all scientific and engineering applications, but to reach its full potential, the problems of both hardware and software must be addressed. This project will develop new codes to take advantage of this new level of computing power. This project will develop a diagnostic tool that will decrease the cost of operating sources of highly charged ions that are used in nuclear physics research as well as industrial applications. This project proposes to explore the feasibility of using the Archimedes Plasma Mass Filter to augment chemical processing of spent nuclear fuel, thereby potentially reducing the cost and environmental impact of recycling nuclear fuel. Z-pinches are cost-effective and efficient; converting stored electrical energy directly into plasma energy and generating much higher confining magnetic fields than can be externally imposed. Their simple linear geometry, yet only partly understood behavior, makes them an attractive challenge both for basic plasma physics and for industrial applications.
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Accelogic
Accelogic, LLC is a Weston, FL based company that has received a grant(s) from the Department of Energy's SBIR/STTR program. The abstract(s) for these grant award(s) are provided as well since they provide insights into Accelogic, LLC's business and areas of expertise. This project will develop technology focused on attaining supercomputing speedups for the "least-squares problem" of at least 1,000x. Field Programmable Gate Arrays (FPGAs) are specialized programmable processors that adapt their hardware resources to better tackle the problem at hand. This will enable supercomputer applications (oil & gas, nuclear, weather, aircraft design, etc.) to exploit FPGAs to solve mathematical equations hundreds of times faster than traditional computers-at lower costs. To attain DOE's stated scientific priorities, quantum increases in large-scale computing and simulation speeds are needed. This project will accelerate critical scientific software by providing breakthrough low-cost technology (Extremely-Fast FPGA-Based Direct Sparse Linear Solvers) that can reduce computational times from months to hours, and days to seconds, thus revolutionizing entire industrial design cycles and the way we do science in general. This project will develop an FPGA software library that will enable unprecedented computational power for the solution of very hard numerical problems (energy fusion research, etc). The solution will work up to 1,000 faster than current microprocessors, and will provide revolutionary added capability to supercomputers for certain problems.