NASA Invests in 18 Potentially Revolutionary Space Tech Concepts
Smart spacesuits and solar surfing may sound like the stuff of science fiction, but they are just two of the technology concepts NASA has selected for further research as part of the NASA Innovative Advanced Concepts (NIAC) program. The program will fund 18 studies to determine the feasibility of early-stage technologies that could go on to change what’s possible in space.
The funded technologies have the potential to transform human and robotic exploration of other worlds, including the Moon and Mars. One researcher, for example, will study an affordable way to mine the ample ice at the Moon’s polar regions. NASA aims to send astronauts to land on the Moon’s south pole in five years.
The latest NIAC selections include Phase I and Phase II awards. The selected Phase I studies cover a wide range of innovations. Each Phase I award is valued at approximately $125,000, helping researchers define and analyze their proposed concepts over nine months. If the initial feasibility studies are successful, awardees can apply for Phase II awards.
The new Phase I selections are:
Bioinspired Ray for Extreme Environments and Zonal Exploration (BREEZE): Combines inflatable structures with bio-inspired kinematics to explore and study the atmosphere of Venus
Javid Bayandor, State University of New York, Buffalo
Power Beaming for Long Life Venus Surface Missions: New approach to support a Venus surface mission with power beaming
Erik Brandon, NASA’s Jet Propulsion Laboratory (JPL), Pasadena, California
SmartSuit: An intelligent spacesuit design with soft-robotics, self-healing skin and data collection for extravehicular activity in extreme environments that allows for greater mobility for exploration missions
Ana Diaz Artiles, Texas A&M Engineering Experiment Station, College Station
Dual Use Exoplanet Telescope (DUET): A novel telescope design to find and characterize planetary systems outside the solar system
Tom Ditto, 3DeWitt LLC, Ancramdale, New York
Micro-Probes Propelled and Powered by Planetary Atmospheric Electricity (MP4AE): Similar to the ballooning capabilities of spiders, these floating microprobes use electrostatic lift to study planetary atmospheres
Yu Gu, West Virginia University, Morgantown
Swarm-Probe Enabled ATEG Reactor (SPEAR) Probe: An ultra-lightweight nuclear electric propulsion probe for deep space exploration, designed to keep mass and volume low for commercial launch
Troy Howe, Howe Industries LLC, Tempe, Arizona
Ripcord Innovative Power System (RIPS): An investigation of a drag using ripcord unspooling power system for descent probes into planets with atmospheres, such as Saturn
Noam Izenberg, Johns Hopkins University, Laurel, Maryland
Power for Interstellar Fly-By: Power harvesting from ultra-miniature probes to enable interstellar missions
Geoffrey Landis, NASA’s Glenn Research Center, Cleveland
Lunar-Polar Propellant Mining Outpost (LPMO): Affordable lunar pole ice mining for propellant production
Joel Serce, TransAstra Corporation, Lake View Terrace, California
Crosscutting High Apogee Refueling Orbital Navigator (CHARON): Novel system for small space debris mitigation
John Slough, MSNW LLC, Redmond, Washington
Thermal Mining of Ices on Cold Solar System Bodies: Proposes using a unique heat application on frozen volatiles and other materials for resource extraction
George Sowers, Colorado School of Mines, Golden
Low-Cost SmallSats to Explore to Our Solar System’s Boundaries: A design for a low-cost, small satellite heliophysics mission to the outer solar system
Robert Staehle, JPL
Phase II studies allow researchers to further develop concepts, refine designs and start considering how the new technology would be implemented. This year’s Phase II selections address a range of cutting-edge concepts from flexible telescopes to new heat-withstanding materials. Awards under Phase II can be worth as much as $500,000 for two-year studies.
The 2019 Phase II selections are:
The High Étendue Multiple Object Spectrographic Telescope (THE MOST): A new, flexible optical telescope design that can be a deployed in a cylindrical roll and installed upon delivery, on a 3D printed structure
Tom Ditto, 3DeWitt LLC, Ancramdale, New York
Rotary-Motion-Extended Array Synthesis (R-MXAS): A geostationary synthetic aperture imaging radiometer with a rotating tethered antenna
John Kendra, Leidos, Inc., Reston, Virginia
Self-Guided Beamed Propulsion for Breakthrough Interstellar Missions: An effort to advance self-guided beamed propulsion technology
Chris Limbach, Texas A&M Engineering Experiment Station, College Station
Astrophysics and Technical Lab Studies of a Solar Neutrino Spacecraft Detector: A small-scale neutrino detector study to advance detector technology for future probe missions
Nickolas Solomey, Wichita State University, Kansas
Diffractive LightSails: A study to design and advance passive and electro-optically active diffractive films for missions in low-Earth orbit, inner solar orbits and to distant stars
Grover Swartzlander, Rochester Institute of Technology, New York
Solar Surfing: A materials-science study to determine the best protective materials to enable heliophysics missions closer to the Sun
Doug Willard, NASA’s Kennedy Space Center, Cape Canaveral, Florida
NASA selected Phase I and II proposals through a peer-review process that evaluates innovativeness and technical viability. All projects are still in the early stages of development, most requiring a decade or more of concept maturation and technology development.
For the first time this summer, the NIAC program will select one Phase III research study. The award will be up to $2 million for as long as two years. This final phase is designed to strategically transition a NIAC concept with the highest potential impact to NASA, other government agencies, or commercial companies.
For more information, visit https://www.nasa.gov/spacetech.