NASA has selected eight technology proposals for investment that have the potential to transform future aerospace missions, introduce new capabilities and significantly improve current approaches to building and operating aerospace systems.
Awards under Phase II of the NASA Innovative Advanced Concepts (NIAC) Program can be worth as much as $500,000 for a two-year study and allow proposers to further develop concepts funded by NASA for Phase I studies that successfully demonstrate initial feasibility and benefit.
“The NIAC program is one of the ways NASA engages the US scientific and engineering communities, including agency civil servants, by challenging them to come up with some of the most visionary aerospace concepts,” says Steve Jurczyk, associate administrator of NASA’s Space Technology Mission Directorate in Washington. “This year’s Phase II fellows have clearly met this challenge.”
Phase II studies allow awardees to refine designs and explore aspects of implementing the new technology. This year’s Phase II portfolio addresses a range of leading-edge concepts, including a method to produce “solar white” coatings for scattering sunlight and cooling fuel tanks in space down to -300 °F with no energy input needed.
NASA selected these projects through a peer-review process that evaluated innovativeness and technical viability. “Phase II decisions are always challenging but we were especially challenged this year with so many successful Phase I studies applying to move forward with their cutting-edge technologies,” says Jason Derleth, the NIAC program executive at NASA Headquarters in Washington. “Whether it’s tensegrity habitats in space, new ways to get humans to Mars, delicate photonic propulsion or any one of the other amazing Phase II studies NIAC is funding, I’m thrilled to welcome these innovations and their innovators back to the program. Hopefully, they will all go on to do what NIAC does best—change the possible.”
The selected concepts are:
- Advancing Torpor Inducing Transfer Habitats for Human Stasis to Mars, John Bradford, Space Works, Inc. in Atlanta
- Cryogenic Selective Surfaces, Robert Youngquist, Kennedy Space Center in Florida
- Directed Energy Interstellar Study, Philip Lubin, University of California, Santa Barbara
- Experimental Demonstration and System Analysis for Plasmonic Force Propulsion, Joshua Rovey, University of Missouri in Rolla
- Flight Demonstration of Novel Atmospheric Satellite Concept, William Engblom, Embry-Riddle Aeronautical University in Daytona Beach, Florida
- Further Development of Aperture: A Precise Extremely Large Reflective Telescope Using Re-configurable Elements, Melville Ulmer, Northwestern University in Evanston, Illinois
- Magnetoshell Aerocapture for Manned Missions and Planetary Deep Space Orbiters, David Kirtley, MSNW, LLC in Redmond, Washington
- Tensegrity Approaches to In-Space Construction of a 1g Growable Habitat, Robert Skelton, Texas Engineering Experiment Station in La Jolla, California
All the projects are still in the early stages of development, most requiring 10 or more years of concept maturation and technology development before use on a NASA mission.