NASA STTR 2018-I Solicitation

Proposal Summary

 18-1- T6.01-1733
 Innovative Solutions to Carbon Dioxide Removal for Spacecraft, Surface Systems, and EVA Systems
 Plug and Play: Utilizing MOFs in Preexisting Carbon Dioxide Removal Assemblies for Enhanced Performance, Smaller Footprint, and Lower Energy Consumption.
Name:   NuMat Technologies
Name:   Northwestern University
Street:  8025 Lamon Avenue
Street:  633 Clark St
City:   Skokie
City:   Evanston
State/Zip:  IL  60077-5315
State/Zip:   IL 
Phone:  (847) 929-4186
Phone:   (847) 467-4934

Principal Investigator (Name, E-mail, Mail Address, City/State/Zip, Phone)
Dr. William Morris
8025 Lamon Avenue Skokie, IL 60077 - 5315
(847) 929-4186

Business Official (Name, E-mail, Mail Address, City/State/Zip, Phone)
Dr. William Morris
8025 Lamon Avenue Skokie, IL 60077 - 5315
(847) 929-4186
Estimated Technology Readiness Level (TRL) :
Begin: 2
End: 4
Technical Abstract

Protection against the buildup of CO2 in spacecraft is of crucial importance to astronaut health. Currently, several methods are used to remove CO2 from spacecraft including amine scrubbers, lithium hydroxide canisters, and adsorbent-based carbon dioxide removal assemblies (CDRAs). Each scrubbing method has individual benefits and drawbacks: amine scrubbers have no particulate release but require high-energy regeneration; lithium hydroxide offers high capacity but the canisters are non-regenerable; and CDRAs offer moderate regeneration but suffer from dusting. The ideal unit would afford high CO2 capacity, low regeneration costs, minimized footprint and weight, and minimal particulate release.

CDRAs, the preferred technology of NASA, currently utilize beds of Zeolite 5A and Zeolite 13x to remove CO2 and H2O, respectively. The drawbacks of this system are a result of the zeolite. Zeolites are a restrictive class of materials, where the inability to tune the material prevents further improvements in the CDRA system.  Furthermore, utilizing zeolites in different environments beyond the CDRA system may further highlight the weakness of these materials for CO2 management.

In contrast to zeolites, metal-organic frameworks (MOFs) are a diverse class of chemically tunable adsorbents.  NuMat Technologies (NuMat) proposes displacing zeolites in CDRA systems with MOFs, enhancing the properties of these systems. The ability to displace the water and carbon dioxide zeolites with a MOF will be evaluated. In addition, the ability of MOFs to be employed in other CO2 management environments will be investigated. During Phase I, NuMat will develop an understanding of how MOFs can enhance existing systems by utilizing the components of the system and simply replacing the zeolite bed with MOFs. This protocol of utilizing existing engineered systems will allow for MOFs to be rapidly transitioned through later technology readiness levels.   

Potential NASA Applications

This phase one application will allow NuMat Technologies to understand how a new class of adsorbents, metal-organic frameworks (MOFs), can be employed in CO2 management systems. This has the potential to be employed in multiple NASA applications. Primarily, these materials will be used to upgrade existing CDRA systems offering enhanced performance. Secondly, these materials have the potential to be employed in other CO2 management systems for use in surface systems and EVA systems.

Potential Non-NASA Applications

The work under this grant has the potential to be used in a wide range of Non-NASA applications. CO2 control is important in other confined environments including rebreather applications and onboard submarines. With mounting concerns about the environment, these materials have the potential to be scaled further and used in H2O harvesting and CO2 sequestration applications. NuMat Technologies is dedicated to investigating these applications as we seek to utilize MOFs in commercial applications.

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