NASA STTR 2019-II Solicitation

Proposal Summary

Proposal Information

Proposal Number:
19-2- T6.06-4319
Phase 1 Contract #:
Subtopic Title:
Spacecraft Water Sustainability through Nanotechnology
Proposal Title:
Controlling Silver Release from Antimicrobial Surface Coatings for Biofouling Control
Cactus Materials
7700 South River Parkway
Chandler AZ  85284 - 1808
Phone: (480) 213-4704
Arizona State University
660 S College Avenue # 507
AZ  85281 - 2480
Phone: (480) 965-4028

Principal Investigator (Name, E-mail, Mail Address, City/State/Zip, Phone)

Mohammed Rafiqul Islam
7700 S River Parkway Chandler, AZ 85284 - 1808
(480) 213-4704

Business Official (Name, E-mail, Mail Address, City/State/Zip, Phone)

Mohammed Rafiqul Islam
7700 S River Parkway Chandler, AZ 85284 - 1808
(480) 213-4704
Estimated Technology Readiness Level (TRL) :
Begin: 4
End: 6
Technical Abstract (Limit 2000 characters, approximately 200 words)

Silver nanoparticles (Ag NPs) are used for the functionalization of surfaces in order to achieve antimicrobial properties and control biofilm growth. The antimicrobial activity of Ag NPs is attributed to the release of Ag + ion, which means that Ag NPs need to be soluble to achieve microbial inactivation. However, because of this constant silver release, Ag NPs rapidly dissolve away from the surface,
depleting the biocidal activity and limiting the use of Ag NPs for long term biofouling control. In Phase I of this project, the team led by Cactus Materials Inc. demonstrated that Ag NPs can be passivated with less soluble forms of silver, such as Ag 2 S, AgBr, or AgI, to slow down silver release and extend the lifetime of Ag NPs-based antimicrobial coatings. When different passivation chemistries were  compared, sulfidation of Ag NPs was found to have the best performance in terms of both slow silver release and high antimicrobial performance. The improved anti-biofouling performance is attributed to the higher retention of silver on the surface over time. A green chemistry approach was developed to functionalize surfaces in situ using a flow through system with reagents of Toxicity Class II or lower. The passivated silver coatings were shown to be compatible with the current use of aqueous AgF for water treatment and storage in the International Space Station. Phase II of this project will evaluate how to coat surfaces comprised of different materials or having complex morphologies with the passivated silver coating developed in Phase I. Long term anti-biofouling performance will be assessed in a dormancy scenario of up to a year. Release of chemicals and particles during the dormancy period will be assessed to identify any risk to the water quality from long term exposure to the passivated silver coatings. The results of this research will establish the capacity of the
proposed innovation to control biofilm in a wide variety of structures for extended periods of time. 

Potential NASA Applications (Limit 1500 characters, approximately 150 words)

U.S. space exploration missions have long considered returning to the Moon and exploration of Mars that challenge life support systems. A potable water treatment process is needed to prevent microbial growth in the long duration missions. Silver have been proven by NASA to be effective for microbial control, however, there remain significant challenges on its fast dissolution rate for an effective solution at preventing biofilm formation. In addition to, another application is in water processor assembly (WPA) here biofoulings are persistent

Potential Non-NASA Applications (Limit 1500 characters, approximately 150 words)

There are unmet needs in current pandemic environment to disinfect tough surfaces including vehicles, air transportation, mass transits and many others. This coating system is expected to antimicrobial at the surface and maintain antimicrobial activity despite wear and environmental exposure. Other applications are included water membranes, textile cloths, and medicals metallic coatings

Duration: 24

Form Generated on 06/27/2021 15:52:33