2212740
Project Grant
Overview
Grant Description
Sbir Phase I: Low-Cost Domestic Additive Manufacturing for Silicon Solar Cells -The broader impact/commercial potential of the Small Business Innovation Research (SBIR) Phase I project is to demonstrate the feasibility of producing high-efficiency, low-cost, crystalline silicon photovoltaic solar cells without using silicon wafers. For the first time, additive manufacturing processes will be applied to silicon in order to produce equivalent performance to silicon wafers without the wasteful processes used in current manufacturing.
If successful, this additive approach can link the parts of the solar supply chain that still exist in the United States?silicon refining and solar module assembly, establishing a full domestic supply chain for this critical energy technology. This supply chain can: (A) be built with off-the-shelf equipment at a third the cost of building traditional silicon wafer and cell factories, (B) cut the cost of photovoltaic solar cell manufacturing in half compared to imported silicon wafer-based solar cells, and (C) reduce energy consumption in solar cell manufacturing by 70% and reduce water consumption by 90%.
This combination of low factory and production costs can drive the growth needed in the solar industry to support the nation?s decarbonization goals while creating tens of thousands of domestic jobs. This SBIR Phase I project seeks to demonstrate the feasibility of a novel architecture and additive manufacturing process for crystalline silicon photovoltaic solar cells that provide equivalent performance to traditional silicon wafer-based solar cells at lower cost with a local supply chain.
The steps in the process flow are adapted from traditional solar cell processing or adjacent industries like microelectronics, but they are being combined in new way to realize this solar cell design. These steps will be co-optimized to produce high-efficiency cells using a series of designed experiments. These processes typically fall into three categories: (1) chemical or physical vapor deposition, (2) solution-based coating, and (3) thermal annealing, with their own relevant process variables: (A) time, temperature, pressure, gas flow rates, and magnetic power; (B) solvent, solution concentration, coating gap, and coating speed; (C) temperature vs. time.
These process variables for each step will be correlated to physical properties of the layers in the cell stack such as thickness, stoichiometry, and performance of the finished cells to produce a prototype with performance that is compelling to investors, partners, and customers.
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.
If successful, this additive approach can link the parts of the solar supply chain that still exist in the United States?silicon refining and solar module assembly, establishing a full domestic supply chain for this critical energy technology. This supply chain can: (A) be built with off-the-shelf equipment at a third the cost of building traditional silicon wafer and cell factories, (B) cut the cost of photovoltaic solar cell manufacturing in half compared to imported silicon wafer-based solar cells, and (C) reduce energy consumption in solar cell manufacturing by 70% and reduce water consumption by 90%.
This combination of low factory and production costs can drive the growth needed in the solar industry to support the nation?s decarbonization goals while creating tens of thousands of domestic jobs. This SBIR Phase I project seeks to demonstrate the feasibility of a novel architecture and additive manufacturing process for crystalline silicon photovoltaic solar cells that provide equivalent performance to traditional silicon wafer-based solar cells at lower cost with a local supply chain.
The steps in the process flow are adapted from traditional solar cell processing or adjacent industries like microelectronics, but they are being combined in new way to realize this solar cell design. These steps will be co-optimized to produce high-efficiency cells using a series of designed experiments. These processes typically fall into three categories: (1) chemical or physical vapor deposition, (2) solution-based coating, and (3) thermal annealing, with their own relevant process variables: (A) time, temperature, pressure, gas flow rates, and magnetic power; (B) solvent, solution concentration, coating gap, and coating speed; (C) temperature vs. time.
These process variables for each step will be correlated to physical properties of the layers in the cell stack such as thickness, stoichiometry, and performance of the finished cells to produce a prototype with performance that is compelling to investors, partners, and customers.
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
Funding Goals
THE GOAL OF THIS FUNDING OPPORTUNITY, "SMALL BUSINESS INNOVATION RESEARCH (SBIR) PROGRAM PHASE I", IS IDENTIFIED IN THE LINK: HTTPS://WWW.NSF.GOV/PUBLICATIONS/PUB_SUMM.JSP?ODS_KEY=NSF21562
Grant Program (CFDA)
Awarding Agency
Place of Performance
Oakland,
California
94609-3406
United States
Geographic Scope
Single Zip Code
Related Opportunity
21-562
Analysis Notes
Amendment Since initial award the End Date has been extended from 11/30/23 to 02/28/25 and the total obligations have decreased 50% from $511,772 to $255,886.
Leap Photovoltaics was awarded
Project Grant 2212740
worth $255,886
from in March 2023 with work to be completed primarily in Oakland California United States.
The grant
has a duration of 2 years and
was awarded through assistance program 47.084 NSF Technology, Innovation, and Partnerships.
SBIR Details
Research Type
SBIR Phase I
Title
SBIR Phase I:Low-cost Domestic Additive Manufacturing for Silicon Solar Cells
Abstract
The broader impact/commercial potential of the Small Business Innovation Research (SBIR) Phase I project is to demonstrate the feasibility of producing high-efficiency, low-cost, crystalline silicon photovoltaic solar cells without using silicon wafers. For the first time, additive manufacturing processes will be applied to silicon in order to produce equivalent performance to silicon wafers without the wasteful processes used in current manufacturing. If successful, this additive approach can link the parts of the solar supply chain that still exist in the United States—silicon refining and solar module assembly, establishing a full domestic supply chain for this critical energy technology. This supply chain can: (a) be built with off-the-shelf equipment at a third the cost of building traditional silicon wafer and cell factories, (b) cut the cost of photovoltaic solar cell manufacturing in half compared to imported silicon wafer-based solar cells, and (c) reduce energy consumption in solar cell manufacturing by 70% and reduce water consumption by 90%.This combination of low factory and production costs can drive the growth needed in the solar industry to support the nation’s decarbonization goals while creating tens of thousands of domestic jobs._x000D_ _x000D_ This SBIR Phase I project seeks to demonstrate the feasibility of a novel architecture and additive manufacturing process for crystalline silicon photovoltaic solar cells that provide equivalent performance to traditional silicon wafer-based solar cells at lower cost with a local supply chain. The steps in the process flow are adapted from traditional solar cell processing or adjacent industries like microelectronics, but they are being combined in new way to realize this solar cell design. These steps will be co-optimized to produce high-efficiency cells using a series of designed experiments. These processes typically fall into three categories: (1) chemical or physical vapor deposition, (2) solution-based coating, and (3) thermal annealing, with their own relevant process variables: (a) time, temperature, pressure, gas flow rates, and magnetic power; (b) solvent, solution concentration, coating gap, and coating speed; (c) temperature vs. time. These process variables for each step will be correlated to physical properties of the layers in the cell stack such as thickness, stoichiometry, and performance of the finished cells to produce a prototype with performance that is compelling to investors, partners, and customers._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 11/7/24
Period of Performance
3/15/23
Start Date
2/28/25
End Date
Funding Split
$255.9K
Federal Obligation
$0.0
Non-Federal Obligation
$255.9K
Total Obligated
Activity Timeline
Transaction History
Modifications to 2212740
Additional Detail
Award ID FAIN
2212740
SAI Number
None
Award ID URI
SAI EXEMPT
Awardee Classifications
Small Business
Awarding Office
491503 TRANSLATIONAL IMPACTS
Funding Office
491503 TRANSLATIONAL IMPACTS
Awardee UEI
UKMZJ7NM6HD7
Awardee CAGE
8HRV7
Performance District
CA-12
Senators
Dianne Feinstein
Alejandro Padilla
Alejandro Padilla
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) | $255,886 | 100% |
Modified: 11/7/24