NASA Marshall Space Flight Center


FLC Region

Security Lab



Technology Transfer Department
Code ZP30
Huntsville, AL 35812
United States

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Laboratory Representative




The Marshall Space Flight Center, located in Huntsville, Ala., is one of NASA's largest and most diversified installations. Today, the Marshall Center is contributing its collective expertise, ingenuity and energy as NASA and the nation carry out the Vision for Space Exploration, which seeks to extend human presence across the solar system. Engineers and scientists at the Marshall Center use state-of-the-art equipment and facilities to accomplish NASA's mission. Marshall manages the key propulsion hardware and technologies of the space shuttle, develops the next generation of space transportation and propulsion systems, oversees science and hardware development for the International Space Station, manages projects and direct studies that will help pave the way back to the moon, and handles a variety of associated scientific endeavors to benefit space exploration and improve life here on Earth. The Marshall Center has been a key contributor to numerous significant NASA programs during the Agency's 45-plus-year history - from the 1961 flight of the first U.S. astronaut into space, to the Apollo missions exploring the moon, to development and operation of America's space shuttle fleet, and construction of and scientific discovery on board the space station.

Technology Disciplines

Displaying 1 - 10 of 525
A Bright Idea for the Eyes
A Faster Fastener
A Leak Monitor for Industry
A Method for Producing Compound Semiconductors
A Method for Producing Compound Semiconductors
A Method for Producing Compound Semiconductors
A Method for Producing Compound Semiconductors
A Method for Producing Compound Semiconductors
A Method for Producing Compound Semiconductors
A Method for Producing Compound Semiconductors


Displaying 21 - 30 of 154
ED Coldflow R & D Test Complex 4776
ED Liquid Rocket Engine Air Flow Fac 4777
ED Liquid/Solid Rocket Eng Water Flow Fac 4776
ED Pump Test Equipment Facility 4777
ED Solid Rocket Engine Air Flow Fac 4777
ED Water Flow Inducer Test Loop 4777
EH Advanced Bonding Technology Laboratory 4707
EH Ambient & High Pressure LOX/GOX Facility 4623
EH Ceramics Coatings & High Temp Mat.Lab 4612
EH Computer Aided Design (CAD)Room 4708



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The Experimental Program to Stimulate Competitive Research,or EPSCoR,establishes partnerships with government, higher education and industry that are designed to effect lasting improvements in a state's or region's research infrastructure, R&D capacity and hence, its national R&D competitiveness.

The EPSCoR program is directed at those jurisdictions that have not in the past participated equably in competitive aerospace and aerospace-related research activities. Twenty-four states, the Commonwealth of Puerto Rico, the U.S. Virgin Islands, and Guam currently participate.Fivefederal agencies conduct EPSCoR programs, including NASA.

NASA EPSCoR Jurisdictions and their Directors
View EPSCoR Directors by State/Jurisdiction

The goal of EPSCoR is to provide seed funding that will enable jurisdictions to develop an academic research enterprise directed toward long-term, self-sustaining, nationally-competitive capabilities in aerospace and aerospace-related research.

Lab Representatives

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Rocket launches—or earthquakes—are already punishing experiences. But it turns out there are some things that can make them worse: like if the vibrations hit the structure you’re in at just the right frequency to cause resonance, where the vibrations become self-reinforcing and get bigger and bigger, in some cases up from bearable to all-out disastrous.

But what if you could turn off that resonance with the flip of a switch?

NASA took on the problem when engineers at Marshall Space Flight Center discovered in testing that the Ares I launch vehicle displayed a serious vibration problem that could be potentially hazardous to the crew sitting right above the booster.

Their solution, appropriating the mass of the hydrogen fuel in the second-stage rocket to dampen the vibrations, worked better than they had even imagined. In testing, “they were getting a knock-down on vibrations that was 50 to 100 times more than could be explained,” recalls project manager Rob Berry.

Team members began to realize they hadn’t designed a variation of standard dampers—they’d come up with something fundamentally new. 

When they put their new device in the fuel tank, they expected to dissipate the force of the vibrations into the liquid. But instead, they realized they were actually causing the fluid to act as if it was no longer part of the spacecraft structure, which meant the resonance no longer occurred.

The result, a brand-new, low-cost, lightweight damper, could become the industry standard for buildings, bridges, and many other structures susceptible to vibrating or shaking. New York City-based Thornton Tomasetti markets the technology to make buildings safer against the wind and from earthquakes. The first device to hit the market was installed in a Brooklyn building constructed in 2016.

“This is a clear paradigm shift versus what we’ve been taught,” Berry says. “It’s hard for people to give up a century’s worth of thinking. But we’ve made that century’s worth of thinking obsolete.”


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