ALBUQUERQUE, N.M. — Sandia National Laboratories researchers — competing in an international pool that includes universities, start-ups, large corporations, and government labs — received five R&D 100 Awards this year, and played a role in a sixth.
R&D Magazine presents the awards each year to researchers who have developed the year’s 100 most outstanding advances in applied technologies.
The six Sandia award winners were:
- A high-temperature silicon carbide power module that more efficiently converts electrical energy from one form to another.
R&D100 Winner 2009: SiC Power Module
- An ultra-low-power silicon microphotonic communications platform that enables optical data transmission and routing on a silicon platform at nanosecond switching speeds with up to 100-times less power consumption and 100 times the bandwidth density compared to traditional electronic approaches.
R&D100 Winner 2009: Ultralow-Power Silicon Microphotonic Communications Platform
- The Catamount N-Way (CNW) lightweight kernel, which delivers significant improvements in data access performance for today’s parallel computing applications.
- NanoCoral™ dendritic platinum nanostructures, an innovative nanotechnology for producing platinum catalysts.
R&D100 Winner 2009: NanoCoral
- Sandia’s hyperspectral confocal fluorescence microscope system, which rapidly finds all emitting fluorescence species of an image.
R&D100 Winner 2009: Hyperspectral Confocal Fluorescence Microscope System
- Artificial retina project, part of a large multilab/industry project funded by DOE.
Sometimes referred to as “the Nobel Prizes of technology,” the R&D 100 awards were first presented in 1963 as the I-R 100s, in keeping with the original name of the magazine, Industrial Research.
The sole criterion for winning, according to a description released by the magazine, is “demonstrable technological significance compared with competing products and technologies.” Properties noted by judges include smaller size, faster speed, greater efficiency and higher environmental consciousness.
Many entries over the ensuing years became household names, including Polacolor film (1963), the flashcube (1965), the automated teller machine (1973), the halogen lamp (1974), the fax machine (1975), the liquid crystal display (1980), the printer (1986), the Kodak Photo CD (1991), the Nicoderm antismoking patch (1992), Taxol anticancer drug (1993), lab on a chip (1996) and HDTV (1998).
“The Department of Energy’s national laboratories are incubators of innovation, and I’m proud they are being recognized once again for their remarkable work,” said Energy Secretary Steven Chu. “The cutting-edge research and development being done in our national labs is vital to maintaining America’s competitive edge, increasing our nation’s energy security and protecting our environment. I want to thank this year’s winners for their work and congratulate them on this award.”
Team members will receive their awards at R&D Magazine’s formal awards banquet on Nov. 12, 2009, at the Renaissance Orlando Hotel at SeaWorld in Florida.
The following is additional information on each of the inventions:
- High-temperature silicon carbide power module. It more efficiently converts electrical energy from one form to another. This invention reduces the size and volume of power electronic systems by an order of magnitude over present state-of-the-art silicon-based solutions while simultaneously reducing energy loss by greater than 50 percent, offering the potential for users to save hundreds of millions of dollars. Applications are in hybrid and electric vehicles, renewable energy interfaces and aircraft.
- Ultra-low-power silicon microphotonic communications platform. An ultra-low-power microphotonic communications platform, made of silicon, for wavelength division multiplexed communications within high performance computers. The ultrasmall components establish a platform of elements capable of addressing the bandwidth and power consumption problems of high-performance computer and data communications networks. Silicon resonant modulators demonstrate for the first time 100-microwatts/gigabit/second optical data transmission on a silicon CMOS-compatible platform. Together with the first high-speed silicon bandpass switches, the platform enables optical data transmission and routing on a silicon platform at nanosecond switching speeds with up to 100-times less power consumption and 100 times the bandwidth density compared to traditional electronic approaches.
- Catamount N-Way (CNW) lightweight kernel. It leverages hardware capabilities of multicore processors to deliver significant improvements in data access performance for today’s parallel computing applications. CNW provides enhanced data access capabilities beyond other equivalent operating systems by employing a new technique that targets memory bandwidth, arguably the most important area of performance in scientific parallel computing. The CNW software is licensed to Cray, Inc., at a non-disclosed price.
- NanoCoral™ dendritic platinum nanostructures. This innovative nanotechnology for producing platinum catalysts offers unique control over the shape, size, porosity, composition, stability and other functional properties of platinum nanostructures compared with those achieved by existing methodologies. Novel catalysts and electrocatalysts produced by the Sandia approach are expected to significantly reduce platinum metal usage and thus the cost of platinum catalysts in fuel cells, solar cells and other applications in the renewable energy sector.
- Hyperspectral confocal fluorescence microscope system. It rapidly finds all emitting fluorescence species of an image, determining their relative concentrations without any a priori information. This patent-pending technology has been combined with Sandia’s proprietary algorithms to form a complete system for the extraction of quantitative image information at diffraction-limited spatial resolutions of 250 nanometers (nm) in the x and y planes and 600 nm in z. The speed with which this information is acquired exceeds the acquisition of other available hyperspectral imaging microscopes.
- Artificial retina project. Sandia shares a part of this award for moving research forward to enable the blind to see. The project employs a small video camera on a patient’s glasses sending images to a compact image processor on the patient’s belt. The processor commands an implant to deliver the desired pulse of current to an electrode array attached to the patient’s retinal tissue. This inner-eye array stimulates the retinal tissue nerves which ultimately connect to nerves leading to the visual cortex of the brain where the patient sees an image . The award was given to a multi-lab/industry collaboration funded by DOE, initiated by Oak Ridge National Laboratory, and submitted for an award by Lawrence Livermore National Laboratory. Sandia is developing microelectromechanical systems (MEMS) and high-voltage subsystems for advanced artificial retina implant designs. These include microtools, electronics packaging, and application-specific integrated circuits (ASICs).
Sandia is a multiprogram laboratory operated by Sandia Corporation, a wholly owned subsidiary of Lockheed Martin, for the U.S. Department of Energy’s National Nuclear Security Administration. With main facilities in Albuquerque, N.M., and Livermore, Calif., Sandia has major R&D responsibilities in national security, energy and environmental technologies, and economic competitiveness.
Sandia news media contact: Neal Singer, firstname.lastname@example.org (505) 845-7078