WASHINGTON — NASA’s Space Technology Program is turning science fiction into science fact. The program has selected 28 proposals for study under the NASA Innovative Advanced Concepts (NIAC) Program.
Eighteen of these advanced concept proposals were categorized as Phase I and 10 as Phase II. They were selected based on their potential to transform future aerospace missions, enable new capabilities, or significantly alter and improve current approaches to launching, building and operating aerospace systems.
The selected proposals include a broad range of imaginative concepts, including a submarine glider to explore the ice-covered ocean of Europa, an air purification system with no moving parts, and a system that could use in situ lunar regolith to autonomously build concrete structures on the moon.
“These selections represent the best and most creative new ideas for future technologies that have the potential to radically improve how NASA missions explore new frontiers,” said Michael Gazarik, director of NASA’s Space Technology Program at the agency’s headquarters in Washington. “Through the NASA Innovative Advanced Concepts program, NASA is taking the long-term view of technological investment and the advancement that is essential for accomplishing our missions. We are inventing the ways in which next-generation aircraft and spacecraft will change the world and inspiring Americans to take bold steps.”
NIAC Phase I awards of approximately $100,000 for one year enable proposers to explore basic feasibility and properties of a potential breakthrough concept. NIAC Phase II awards of as much as $500,000 for two years help further develop the most successful Phase I concepts and analyze their potential to enable new or radically improved future NASA missions and potential applications with benefits for industry and society.
“We’re excited to be launching Phase II, allowing the 2012 NIAC portfolio to feature an exciting combination of new ideas and continued development of last year’s Phase I concepts,” said Jay Falker, NIAC program executive at NASA Headquarters.
NASA solicited visionary, long-term concepts for technological maturation based on their potential value to NASA’s future space missions and operational needs. These projects were chosen through a peer-review process that evaluated their innovation and how technically viable they are. All are very early in development — 10 years or longer from use on a mission.
NASA’s early investment and partnership with creative scientists, engineers, and citizen inventors from across the nation will provide technological dividends and help maintain America’s leadership in the global technology economy.
The portfolio of diverse and innovative ideas selected for NIAC awards represent multiple technology areas, including power, propulsion, structures, and avionics, as identified in NASA’s Space Technology Roadmaps. The roadmaps provide technology paths needed to meet NASA’s strategic goals.
NIAC is part of NASA’s Space Technology Program, which is innovating, developing, testing, and flying hardware for use in NASA’s future missions. These competitively-awarded projects are creating new technological solutions for NASA and our nation’s future.
For a complete list of the selected proposals and more information about the NIAC, visit:
http://www.nasa.gov/niac
2012 Phase I Fellows
| Principal Investigator |
Proposal Title |
Organization |
City, State, Zip Code |
| Agogino, Adrian |
Super Ball Bot – Structures for Planetary Landing and Exploration |
NASA ARC |
Moffett Field, CA 94035 |
| Arrieta, Juan |
The Regolith Biters: A Divide-And-Conquer Architecture for Sample |
NASA JPL |
Pasadena, CA 91109-8001 |
| Cohen, Marc |
Robotic Asteroid Prospector (RAP) Staged from L-1: Start of the Deep Space Economy |
Marc M. Cohen, Architect |
Palo Alto, CA 94306-3852 |
| Ditto, Thomas |
HOMES – Holographic Optical Method for Exoplanet Spectroscopy |
3DeWitt LLC |
Ancramdale, NY 12503-0010 |
| Flynn, Michael |
Water Walls: Highly Reliable and Massively Redundant Life Support Architecture |
NASA ARC |
Moffett Field, CA 94035 |
| Gellett, Wayne |
Solid State Air Purification System |
Zettacore Inc. |
Menlo Park, CA 94025-1438 |
| Hoyt, Robert |
NanoTHOR: Low-Cost Launch of Nanosatellites to Deep Space |
Tethers Unlimited, Inc. |
Bothell, WA 98011-8808 |
| Hoyt, Robert |
SpiderFab: Process for On-Orbit Construction of Kilometer-Scale Apertures |
Tethers Unlimited, Inc. |
Bothell, WA 98011-8808 |
| Kirtley, David |
A Plasma Aerocapture and Entry System for Manned Missions and Planetary Deep Space Orbiters |
The Planetary Society |
Redmond, WA 98052-3557 |
| Landis, Geoffrey |
Venus Landsailing Rover |
NASA GRC |
Cleveland, OH 44135-3127 |
| Lantoine, Gregory |
MAGNETOUR: Surfing Planetary Systems on Electromagnetic and Multi-Body Gravity Fields |
NASA JPL |
Pasadena, CA 91109-8001 |
| McCue, Leigh |
Exploration of Under-Ice Regions with Ocean Profiling Agents (EUROPA) |
Virginia Polytechnic Institute and State University |
Blacksburg, VA 24061-0001 |
| Nosanov, Jeffrey |
Solar System Escape Architecture for Revolutionary Science (SSEARS) |
NASA JPL |
Pasadena, CA 91109-8001 |
| Predina, Joseph |
NIST in Space: Better Remote Sensors for Better Science |
ITT Space Systems, LLC |
Fort Wayne, IN 46818-1165 |
| Quadrelli, Marco |
Orbiting Rainbows: Optical Manipulation of Aerosols and the Beginnings of Future Space Construction |
NASA JPL |
Pasadena, CA 91109-8001 |
| Saif, Babak |
Atom Interferometry for detection of Gravity Waves-a |
NASA GSFC |
Greenbelt, MD 20771-2400 |
| Winglee, Robert |
Sample Return Systems for Extreme Environments |
University of Washington, Seattle |
Seattle, WA 98195-1310 |
| Zha, Gecheng |
Silent and Efficient Supersonic Bi-Directional Flying Wing |
University of Miami |
Coral Gables, FL 33146-2509 |
|
2012 Phase II Fellows
| Principal Investigator |
Proposal Title |
Organization |
City, State, Zip Code |
| Duda, Kevin |
Variable Vector Countermeasure Suit (V2Suit) for Space Habitation and Exploration |
Charles Stark Draper Laboratory Inc. |
Cambridge, MA 02139-3539 |
| Khoshnevis, Behrokh |
ISRU-Based Robotic Construction Technologies for Lunar and Martian Infrastructures |
University of Southern California |
Los Angeles, CA 90089-0001 |
| Miller, David |
High-Temperature Superconductors as Electromagnetic Deployment and Support Structures |
Massachusetts Institute of Technology |
Cambridge, MA 02139-4301 |
| Ritter, Joe |
OCCAMS: Optically Controlled and Corrected Active Meta-material Space Structures |
Neoteric Physics, Inc. |
Kihei, HI 96753-9310 |
| Short, Kendra |
Printable Spacecraft: Flexible Electronic Platforms for NASA Missions |
NASA JPL |
Pasadena, CA 91109-8001 |
| Slough, John |
The Fusion Driven Rocket: Nuclear Propulsion through Direct Conversion of Fusion Energy |
MSNW LLC |
Redmond, WA 98052-3557 |
| Strekalov, Dmitry |
Ghost imaging of space objects |
NASA JPL |
Pasadena, CA 91109-8001 |
| Westover, Shayne |
Radiation Protection and Architecture Utilizing High Temperature Superconducting Magnets |
NASA JSC |
Houston, TX 77058-3607 |
| Whittaker, William |
Cavehopping Exploration of Planetary Skylights and Tunnels |
Astrobotic Technology, Inc. |
Pittsburgh, PA 15213-3524 |
| Wie, Bong |
An Innovative Solution to NASA’s NEO Impact Threat Mitigation Grand Challenge and Flight Validation Mission Architecture Development |
Iowa State University |
Ames, IA 50011-2207 |
|
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