2521432
Project Grant
Overview
Grant Description
Collaborative research: FEC: Optical properties of mineral dust aerosols: Building capacity for use-inspired applications through experimental and theoretical investigations.
Mineral dust aerosols are small particles commonly suspended in the Earth's atmosphere with important implications for weather and climate, ecosystems, human health and visibility, and optical communication and remote sensing systems.
Unfortunately, very little is known about the optical properties of mineral dust and how they relate to dust sources and properties.
This understanding is necessary to comprehend the roles and impacts of mineral dust aerosols on human and natural systems.
This project aims to build capacity toward use-inspired research by gaining such understanding through integrated experimental and theoretical investigations of mineral dust optical properties.
This will be of the essence for quantifying mineral dust on global and regional scales, mineral dust effects on weather and climate, and their impacts on human and natural systems.
The project will build a three-state collaborative team to develop and demonstrate capacity for use-inspired research by advancing knowledge on the optical properties of mineral dust aerosols in the atmosphere.
Use-inspired applications include improving optical remote and in situ sensing of mineral dust aerosols.
Additional applications include quantifying mineral dust impacts on human and machine visibility for safe operation of cars and airplanes and on national defense (e.g., optical range finders and target designators) and effects of inhaled mineral dust on human health (e.g., respiratory and pulmonary disease and mortality).
Mineral dust aerosols dominate aerosol mass and aerosol optical depth in the Earth's atmosphere with important implications for radiative forcing and climate, fertilization of aquatic and terrestrial ecosystems, human health and visibility, and optical communication and remote sensing systems.
Unfortunately, very little is known about mineral dust optical properties and how they relate to dust sources and dust physical, chemical, and mineralogical properties as needed to understand the roles and impacts of mineral dust aerosols in the Earth system.
Project outcomes have potential to build capacity toward use-inspired research by gaining such understanding through integrated experimental and theoretical investigations of mineral dust optical properties.
This will be of the essence for quantifying the global and regional mineral dust cycles, mineral dust direct radiative forcing, and their impacts on human and natural systems with optical remote and in situ measurements, thereby addressing key national critical and emerging technologies.
This project aims to build on research excellence and stakeholders in three EPSCoR jurisdictions (Nevada, Oklahoma, and Wyoming) with the following jurisdictions/partner institutions involved:
Nevada (NV): Desert Research Institute (DRI: overall and NV lead institution) and Truckee Meadows Community College (TMCC: NV sub-awardee);
Oklahoma (OK): University of Oklahoma (OU: OK lead institution);
Wyoming (WY): University of Wyoming (UW: WY lead institution) and Central Wyoming College (CWC: WY sub-awardee).
The project combines a breadth of strengths of the three collaborating jurisdictions, including 1) experimental aerosol optics experience, instruments, and facilities at DRI; 2) availability of the unique and well-characterized DRI global mineral dust collection; 3) leading theoretical light-scattering computational capabilities and expertise at UW; 4) capabilities in applied mathematics at TMCC; and 5) leading strengths in aerosol remote sensing at OU.
This project is supported by the EPSCoR Research Infrastructure Improvement Program: Focused EPSCoR Collaborations Program (FEC), which supports interjurisdictional teams of EPSCoR investigators to perform research in topics that align with NSF priorities, with the goals of driving discovery and building sustainable STEM capacity.
This award reflects NSF's statutory mission and has been deemed worthy of support through evaluation using the foundation's intellectual merit and broader impacts review criteria.
Subawards are planned for this award.
Mineral dust aerosols are small particles commonly suspended in the Earth's atmosphere with important implications for weather and climate, ecosystems, human health and visibility, and optical communication and remote sensing systems.
Unfortunately, very little is known about the optical properties of mineral dust and how they relate to dust sources and properties.
This understanding is necessary to comprehend the roles and impacts of mineral dust aerosols on human and natural systems.
This project aims to build capacity toward use-inspired research by gaining such understanding through integrated experimental and theoretical investigations of mineral dust optical properties.
This will be of the essence for quantifying mineral dust on global and regional scales, mineral dust effects on weather and climate, and their impacts on human and natural systems.
The project will build a three-state collaborative team to develop and demonstrate capacity for use-inspired research by advancing knowledge on the optical properties of mineral dust aerosols in the atmosphere.
Use-inspired applications include improving optical remote and in situ sensing of mineral dust aerosols.
Additional applications include quantifying mineral dust impacts on human and machine visibility for safe operation of cars and airplanes and on national defense (e.g., optical range finders and target designators) and effects of inhaled mineral dust on human health (e.g., respiratory and pulmonary disease and mortality).
Mineral dust aerosols dominate aerosol mass and aerosol optical depth in the Earth's atmosphere with important implications for radiative forcing and climate, fertilization of aquatic and terrestrial ecosystems, human health and visibility, and optical communication and remote sensing systems.
Unfortunately, very little is known about mineral dust optical properties and how they relate to dust sources and dust physical, chemical, and mineralogical properties as needed to understand the roles and impacts of mineral dust aerosols in the Earth system.
Project outcomes have potential to build capacity toward use-inspired research by gaining such understanding through integrated experimental and theoretical investigations of mineral dust optical properties.
This will be of the essence for quantifying the global and regional mineral dust cycles, mineral dust direct radiative forcing, and their impacts on human and natural systems with optical remote and in situ measurements, thereby addressing key national critical and emerging technologies.
This project aims to build on research excellence and stakeholders in three EPSCoR jurisdictions (Nevada, Oklahoma, and Wyoming) with the following jurisdictions/partner institutions involved:
Nevada (NV): Desert Research Institute (DRI: overall and NV lead institution) and Truckee Meadows Community College (TMCC: NV sub-awardee);
Oklahoma (OK): University of Oklahoma (OU: OK lead institution);
Wyoming (WY): University of Wyoming (UW: WY lead institution) and Central Wyoming College (CWC: WY sub-awardee).
The project combines a breadth of strengths of the three collaborating jurisdictions, including 1) experimental aerosol optics experience, instruments, and facilities at DRI; 2) availability of the unique and well-characterized DRI global mineral dust collection; 3) leading theoretical light-scattering computational capabilities and expertise at UW; 4) capabilities in applied mathematics at TMCC; and 5) leading strengths in aerosol remote sensing at OU.
This project is supported by the EPSCoR Research Infrastructure Improvement Program: Focused EPSCoR Collaborations Program (FEC), which supports interjurisdictional teams of EPSCoR investigators to perform research in topics that align with NSF priorities, with the goals of driving discovery and building sustainable STEM capacity.
This award reflects NSF's statutory mission and has been deemed worthy of support through evaluation using the foundation's intellectual merit and broader impacts review criteria.
Subawards are planned for this award.
Funding Goals
THE GOAL OF THIS FUNDING OPPORTUNITY, "EPSCOR RESEARCH INFRASTRUCTURE IMPROVEMENT PROGRAM: FOCUSED EPSCOR COLLABORATIONS (FEC)", IS IDENTIFIED IN THE LINK: HTTPS://WWW.NSF.GOV/PUBLICATIONS/PUB_SUMM.JSP?ODS_KEY=NSF24573
Grant Program (CFDA)
Awarding / Funding Agency
Place of Performance
Reno,
Nevada
89512-1095
United States
Geographic Scope
Single Zip Code
Nevada System Of Higher Education was awarded
FEC: Mineral Dust Aerosol Optical Properties Study
Project Grant 2521432
worth $3,260,118
from the NSF Office of Integrative Activities in August 2025 with work to be completed primarily in Reno Nevada United States.
The grant
has a duration of 4 years and
was awarded through assistance program 47.083 Integrative Activities.
The Project Grant was awarded through grant opportunity EPSCoR Research Infrastructure Improvement Program: Focused EPSCoR Collaborations Program (FEC).
Status
(Ongoing)
Last Modified 8/21/25
Period of Performance
8/15/25
Start Date
7/31/29
End Date
Funding Split
$3.3M
Federal Obligation
$0.0
Non-Federal Obligation
$3.3M
Total Obligated
Activity Timeline
Additional Detail
Award ID FAIN
2521432
SAI Number
None
Award ID URI
SAI EXEMPT
Awardee Classifications
Public/State Controlled Institution Of Higher Education
Awarding Office
490106 OFFICE OF INTEGRATIVE ACTIVITIES
Funding Office
490106 OFFICE OF INTEGRATIVE ACTIVITIES
Awardee UEI
MV1JFXA4S621
Awardee CAGE
0K5F8
Performance District
NV-02
Senators
Catherine Cortez Masto
Jacky Rosen
Jacky Rosen
Modified: 8/21/25