Latest milestone from Space Foundry opens new possibilities for in-space on-demand electronics manufacturing

Space Foundry has successfully demonstrated its plasma jet printing technology in microgravity using parabolic flight (G-FORCE ONE, a specially modified Boeing 727-200).  Space Foundry Inc. was founded by DCU Electronic Engineering alumnus Dr. Ram Prasad Gandhiraman and Dr. Dennis Nordlund from Stanford University.

The Space Foundry team printed silver lines, pads, interdigitated electrodes and a wifi-antenna. The development of plasma jet printing for space applications is part of NASA’s On-Demand Manufacturing of Electronics (ODME) project, part of the Game Changing Development Program. 

Plasma jet printing technology is based on the interaction between aerosolized ink and plasma. By carefully controlling the plasma creation process, the electronic structure of the ink materials can be tailored and the oxidation state of the metals can be precisely controlled. The printed pattern is dry and hence no curing is needed. This capability of plasma jet printing is attractive for aerospace and defense customers who are interested in direct-write printing on large curved, non-planar surfaces.

NASA’s interest in plasma jet printing is due to its inherent ability to tailor the electronic structure of materials without additional post-processing and the ability to control fluid flow using an electromagnetic field, making it gravity independent.

The Plasma jet printer used in parabolic flights is a multilateral printing platform that can print a wide range of materials including metals, dielectrics, organics and bioinks. Antennas and interdigitated electrodes printed in zero gravity can have a wide range of In-Space Manufacturing applications including energy harvesting, inventory control, power distribution, bio and gas sensor manufacturing (e.g. as biosensors and gas sensors have limited shelf life, astronauts can produce these sensors on demand). In the future, plasma jet printing can potentially be used as part of the commercialization of low earth orbit and for manufacturing on the lunar surface.

Acknowledgments: The flights were supported by an SBIR Phase II-E award, funded jointly by NASA SBIR and the NASA Flight Opportunities Program. The flight demonstration was funded through NASA contracts 80NSSC19C0136 and 80NSSC21C0427. The antenna design is based on research sponsored, in part, by Air Force Research Laboratory under agreement FA8650-15-2-5401, conducted through the flexible hybrid electronics manufacturing innovation institute, NextFlex.