SBIR-STTR Award

Low Cost Copper Contacts with Built in Barriers for Crystalline Silicon Solar Cells
Award last edited on: 4/27/2022

Sponsored Program
STTR
Awarding Agency
NSF
Total Award Amount
$1,519,995
Award Phase
2
Solicitation Topic Code
MN
Principal Investigator
Ruvini Dharmadasa

Company Information

Bert Thin Films LLC

201 East Jefferson Street Suite 302
Louisville, KY 40202
   (502) 569-1038
   info@bertthinfilms.com
   www.bertthinfilms.com

Research Institution

University of Louisville

Phase I

Contract Number: 1448883
Start Date: 1/1/2015    Completed: 6/30/2016
Phase I year
2015
Phase I Amount
$269,999
The broader impact/commercial potential of this Small Business Technology Transfer (STTR) Phase I project will be to lower manufacturing costs in the photovoltaic (PV) industry. In the past decade, the solar energy industry has seen double digit compound annual growth rates. This success has resulted in the industry consuming nearly 10 percent of the global silver production. The cost of metallization on silicon solar cells has become a notable cost driver for the manufacturers and the lack of stability of silver spot prices increases the volatility in this highly competitive industry. The successful implementation of copper inks would lead to significant cost savings, due to copper being around 100 times cheaper than silver. This project supports a materials research and development for a renewable energy industry that has the potential to offer significant cost savings to a very large industry. This Small Business Technology Transfer (STTR) Phase I project will develop copper based inks and pastes with an in-built diffusion barrier. The inks and pastes will be formulated from copper nanoparticles manufactured in solution phase. During this stage barrier layers will be grown directly upon the particles. This project will study the growth mechanisms of the nanoparticles and performance of the diffusion layer using high tech analysis techniques. The inks will be designed to be thermally processed using intense pulsed light (IPL) treatment, an advanced manufacturing technology. Reaction kinetics during IPL treatment will also be investigated in order to optimize ink formulations. This project will result in the formulation of two copper based inks for screen and ink jet printing, with optimized thermal processing conditions. Metal contacts formed with these inks will show that the barriers mitigate diffusion of copper into silicon and are a viable option for the replacement of the current silver contacts on silicon solar cells.

Phase II

Contract Number: 1660161
Start Date: 4/1/2017    Completed: 3/31/2019
Phase II year
2017
(last award dollars: 2019)
Phase II Amount
$1,249,996

This Small Business Innovation Research Phase II project aims to develop copper based pastes for the metallization of silicon solar cells. Photovoltaics (PV) offer an opportunity for clean and affordable energy and over the past decade the PV industry has seen annual compound growth rates of over 50%. Although revenues are high, the profit margins for many manufacturers have substantially diminished, necessitating the need for cutbacks throughout the value chain. One area marked for cost reduction, is in the metallization of the solar cells, which now commands nearly 10 percent of the world's supply. Having the cost of photovoltaic panels tied to a precious metal with price volatility can lead to higher prices for renewable energy; thus replacing silver with copper is a significant opportunity for the industry. Thus the outcomes of this project would be a product for making solar energy more affordable. The project also includes creating two new full time positions in Kentucky in Advanced Research and Manufacturing. This proposal will enhance scientific understanding of the copper-silicon contact formation and durability of the material during operation. The technological feasibility of the copper pastes with an inherent diffusion barrier was demonstrated on standard and bifacial solar cells in Phase I. Phase II will further improve the screen printable pastes to industry standards. To achieve the high electrical performance required in this market, the project will investigate the copper-silicon interface to investigate the mechanisms involved during contact formation, and the chemical nature of the copper-silicon interface. This information will be used to optimize the chemical composition and thermal treatment of the pastes to improve electrical performance and cell lifetime. The pastes will be optimized for industrial operating equipment to provide the manufacturer with a product that can be dropped in, with minimal changes to the production line. Phase II will also involve scale up of the core materials in the pastes to be able to engage customers in further printing trials. Through the assembly and testing of prototype solar cell modules, the durability of the copper contacts will be demonstrated. The outcomes of this proposal will be screen printable copper pastes that can be direct drop in replacement for the silver pastes; thereby enhancing the profit margins of the solar cell manufacturer.