2151713
Project Grant
Overview
Grant Description
Sbir Phase I: High-Throughput Nanocatalyst Synthesis and Screening for Broad Decarbonization - The Broader Impact/Commercial Potential of This Small Business Innovation Research (SBIR) Phase I Project Is an Acceleration in How New Materials Are Discovered, Designed, and Commercialized in the Transition to a Carbon-Neutral Economy.
One Aim Is to Increase the Use of Renewable Electricity in the Chemical and Energy Industries. A Major Hurdle Is the Lack of Efficient Electrocatalysts That Enable Renewable Processes, Such as Green Hydrogen Production, Carbon Dioxide (CO2) Conversion into Carbon-Neutral Chemicals and Fuels, or Other Processes That Can Broadly Decarbonize Various Industries.
Traditional Discovery Methods Are Slow and Serial, Which Limits the Development of Novel, Commercially Viable Electrochemical Processes Demanded by the Climate Crisis. This Project Will Enable a More Rapid and Exhaustive Search for Electrocatalysts, Resulting in a Deeper Understanding of the Nature of Catalysts, and Facilitating the Decarbonization of the Chemicals and Energy Industries by Displacing Traditional Fossil Fuel-Based Processes with a Transition to Electrification Which Utilizes Increasing Levels of Renewable Energy.
The Proposed Platform Will Expedite the Discovery and Development of Enabling Materials, Which Can Be Brought to Market and Deployed Globally to Enable More Renewable Chemical Processes. This SBIR Phase I Project Proposes to Develop a Generalizable Platform That Can Rapidly Search Through Vast Materials Spaces for Higher Performance Electrocatalyst Materials, Displacing the Current Materials Which Are Simply the Best Amongst the Limited Candidates Tested to Date.
Using This Project's Proprietary Megalibrary Technology, Which Enables the Rapid Synthesis of Libraries of Tens of Thousands of Unique, Well-Defined, Monodisperse, and Complex Metal Nanoparticles in a Single Experiment, Coupled with High-Throughput Screening Technologies, It Is Possible to Quickly Probe Hundreds of Thousands of Unique Catalyst Candidates to Find Electrocatalysts Optimized for Performance.
To Accomplish This Goal, the Project Must Adapt Protocols to Allow the Synthesis of Electrocatalyst Megalibraries on Electrodes and Enable Electrocatalyst Screening. Additionally, the Approach Requires Robust and High-Throughput Screening Methods That Can Site-Specifically Interrogate the Electrocatalytic Properties of the Catalyst Candidates.
Using These Two Innovations, It Will Be Possible to Then Demonstrate the Power of the Platform by Searching the Entirety of a Three Element Platinum and Materials (Pt-M1-M2) Space for the Best Hydrogen Evolution Reaction Catalyst on a Per Platinum-Atom Basis. This Demonstration Will Solidify the Ability to Translate This Platform to a Much Broader Materials Space and Set of Reactions, Which Can Impact Businesses and Industries Globally.
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.
One Aim Is to Increase the Use of Renewable Electricity in the Chemical and Energy Industries. A Major Hurdle Is the Lack of Efficient Electrocatalysts That Enable Renewable Processes, Such as Green Hydrogen Production, Carbon Dioxide (CO2) Conversion into Carbon-Neutral Chemicals and Fuels, or Other Processes That Can Broadly Decarbonize Various Industries.
Traditional Discovery Methods Are Slow and Serial, Which Limits the Development of Novel, Commercially Viable Electrochemical Processes Demanded by the Climate Crisis. This Project Will Enable a More Rapid and Exhaustive Search for Electrocatalysts, Resulting in a Deeper Understanding of the Nature of Catalysts, and Facilitating the Decarbonization of the Chemicals and Energy Industries by Displacing Traditional Fossil Fuel-Based Processes with a Transition to Electrification Which Utilizes Increasing Levels of Renewable Energy.
The Proposed Platform Will Expedite the Discovery and Development of Enabling Materials, Which Can Be Brought to Market and Deployed Globally to Enable More Renewable Chemical Processes. This SBIR Phase I Project Proposes to Develop a Generalizable Platform That Can Rapidly Search Through Vast Materials Spaces for Higher Performance Electrocatalyst Materials, Displacing the Current Materials Which Are Simply the Best Amongst the Limited Candidates Tested to Date.
Using This Project's Proprietary Megalibrary Technology, Which Enables the Rapid Synthesis of Libraries of Tens of Thousands of Unique, Well-Defined, Monodisperse, and Complex Metal Nanoparticles in a Single Experiment, Coupled with High-Throughput Screening Technologies, It Is Possible to Quickly Probe Hundreds of Thousands of Unique Catalyst Candidates to Find Electrocatalysts Optimized for Performance.
To Accomplish This Goal, the Project Must Adapt Protocols to Allow the Synthesis of Electrocatalyst Megalibraries on Electrodes and Enable Electrocatalyst Screening. Additionally, the Approach Requires Robust and High-Throughput Screening Methods That Can Site-Specifically Interrogate the Electrocatalytic Properties of the Catalyst Candidates.
Using These Two Innovations, It Will Be Possible to Then Demonstrate the Power of the Platform by Searching the Entirety of a Three Element Platinum and Materials (Pt-M1-M2) Space for the Best Hydrogen Evolution Reaction Catalyst on a Per Platinum-Atom Basis. This Demonstration Will Solidify the Ability to Translate This Platform to a Much Broader Materials Space and Set of Reactions, Which Can Impact Businesses and Industries Globally.
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.
Awardee
Grant Program (CFDA)
Awarding / Funding Agency
Place of Performance
Skokie,
Illinois
60077-5317
United States
Geographic Scope
Single Zip Code
Related Opportunity
None
Mattiq was awarded
Project Grant 2151713
worth $255,904
from National Science Foundation in February 2023 with work to be completed primarily in Skokie Illinois United States.
The grant
has a duration of 8 months and
was awarded through assistance program 47.084 NSF Technology, Innovation, and Partnerships.
SBIR Details
Research Type
SBIR Phase I
Title
SBIR Phase I:High-throughput Nanocatalyst Synthesis and Screening for Broad Decarbonization
Abstract
The broader impact/commercial potential of this Small Business Innovation Research (SBIR) Phase I project is an acceleration in how new materials are discovered, designed, and commercialized in the transition to a carbon-neutral economy.One aim is to increase the use of renewable electricity in the chemical and energy industries.A major hurdle is the lack of efficient electrocatalysts that enable renewable processes, such as green hydrogen production, carbon dioxide (CO2) conversion into carbon-neutral chemicals and fuels, or other processes that can broadly decarbonize various industries. Traditional discovery methods are slow and serial, which limits the development of novel, commercially viable electrochemical processes demanded by the climate crisis. This project will enable a more rapid and exhaustive search for electrocatalysts, resulting in a deeper understanding of the nature of catalysts, and facilitating the decarbonization of the chemicals and energy industries by displacing traditional fossil fuel-based processes with a transition to electrification which utilizes increasing levels of renewable energy. The proposed platform will expedite the discovery and development of enabling materials, which can be brought to market and deployed globally to enable more renewable chemical processes._x000D_ _x000D_ This SBIR Phase I project proposes to develop a generalizable platform that can rapidly search through vast materials spaces for higher performance electrocatalyst materials, displacing the current materials which are simply the best amongst the limited candidates tested to date. Using this project’s proprietary Megalibrary technology, which enables the rapid synthesis of libraries of tens of thousands of unique, well-defined, monodisperse, and complex metal nanoparticles in a single experiment, coupled with high-throughput screening technologies, it is possible to quickly probe hundreds of thousands of unique catalyst candidates to find electrocatalysts optimized for performance. To accomplish this goal, the project must adapt protocols to allow the synthesis of electrocatalyst Megalibraries on electrodes and enable electrocatalyst screening. Additionally, the approach requires robust and high-throughput screening methods that can site-specifically interrogate the electrocatalytic properties of the catalyst candidates. Using these two innovations, it will be possible to then demonstrate the power of the platform by searching the entirety of a three element platinium and materials (Pt-M1-M2) space for the best hydrogen evolution reaction catalyst on a per platinum-atom basis. This demonstration will solidify the ability to translate this platform to a much broader materials space and set of reactions, which can impact businesses and industries globally._x000D_ _x000D_ 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.
Topic Code
EN
Solicitation Number
NSF 21-562
Status
(Complete)
Last Modified 2/17/23
Period of Performance
2/15/23
Start Date
10/31/23
End Date
Funding Split
$255.9K
Federal Obligation
$0.0
Non-Federal Obligation
$255.9K
Total Obligated
Activity Timeline
Additional Detail
Award ID FAIN
2151713
SAI Number
None
Award ID URI
SAI EXEMPT
Awardee Classifications
Small Business
Awarding Office
491503 TRANSLATIONAL IMPACTS
Funding Office
491503 TRANSLATIONAL IMPACTS
Awardee UEI
RGKQA22SLJR8
Awardee CAGE
94W40
Performance District
Not Applicable
Budget Funding
| Federal Account | Budget Subfunction | Object Class | Total | Percentage |
|---|---|---|---|---|
| Research and Related Activities, National Science Foundation (049-0100) | General science and basic research | Grants, subsidies, and contributions (41.0) | $255,904 | 100% |
Modified: 2/17/23