SBIR-STTR Award

Self-Healing Field-Emission Neutralizers for Electric Propulsion
Award last edited on: 1/14/2015

Sponsored Program
SBIR
Awarding Agency
NASA : JPL
Total Award Amount
$99,986
Award Phase
1
Solicitation Topic Code
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Principal Investigator
Jason M Makela

Company Information

Aerophysics Inc

1402 East Sharon Avenue Suite 206
Houghton, MI 49931
   (906) 370-2376
   jdsommer@mtu.edu
   N/A
Location: Single
Congr. District: 01
County: Houghton

Phase I

Contract Number: ----------
Start Date: ----    Completed: ----
Phase I year
2011
Phase I Amount
$99,986
Electric propulsion (EP) thrusters have the potential to enhance or enable Discovery-class missions. However, a significant challenge in scaling micro (< 100 W) EP devices up as well as scaling macro (> 1 kW) EP devices down is the lack of a compatible neutralizer technology in the meso scale ( < 1 kW). Traditionally, the technology used for spacecraft neutralization has been the hollow cathode, though hollow cathodes require an unsatisfactory fraction of a propulsion system's propellant and power in the meso-scale regime. In fact, they require such a large amount of propellant and power that system efficiency is reduced by 50-100%. In addition, using a hollow cathode causes undesirable specific impulse reduction. The most promising technology for meso-scale neutralizers is field emission (FE), which requires the use of nano-scale sharp emitters and high electric fields to establish a beam of electrons. The drawback of FE devices is that the nano-scale emitters become damaged when operated in elevated pressure environments (10-5 Torr), causing catastrophic failure. The research proposed here is to develop field-emission cathodes for use in meso-scale EP that eliminate tip degradation not through attempts to minimize tip wear, but instead by incorporating self-assembling nanostructures that can repeatedly re-generate damaged emitter tips in space and fully restore the functionality of a damaged or degraded cathode. The procedure is the equivalent of having a MEMS fabrication and repair lab on-board the spacecraft. The re-generable emitters proposed here have been successfully demonstrated in the laboratory in work by Makela, et. al. dating back to 2007. The re-generable neutralizers could enable highly efficient, high-Isp, low-mass propulsion systems operating between a few Watts and 1 kW by either scaling existing micro technologies up or scaling existing macro technologies down.

Phase II

Contract Number: ----------
Start Date: ----    Completed: ----
Phase II year
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Phase II Amount
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