New Approach to Room-Temperature Materials Synthesis - Low Cost, Simple, and Controlled Composition
Templates allow for materials with deliberate sizes and shapes for solar cells and electricity generation from waste heat.
The Science
Templates are being exploited to create new materials for solar cells and other energy-producing devices. Now, a versatile two-step process uses templates of hexagonal nanoplates that controllably transform into more complex materials with specific sizes and shapes. Chemical processes known as ion exchange reactions convert templates of compounds containing two elements to new materials with three elements. The resulting material has controlled size, shape, and composition.
The Impact
This simple approach allows for earth-abundant energy materials to be made with a great degree of control over their chemical composition and shape, at low cost. Scientists used this approach for direct conversion, at room temperature, of copper selenide to a new material, copper silver selenide. This new material is a semiconductor useful for solar cells and converting waste heat to electricity.
Summary
Researchers at the University of Michigan discovered a method for direct conversion, at room temperature, of copper selenide to copper silver selenide, which is a valuable semiconductor. The chemical composition of the reaction product is controlled by adjusting the silver to selenium (Ag:Se) molar ratio in the starting reactants. The shape is controlled by tuning the reaction temperature and time during formation of copper selenide crystals. The approach involves chemical processes called ion exchange reactions. In the ion exchange reactions, the partial removal of smaller copper ions from copper selenide crystals occurs. Immediately, the same amount of slightly larger silver ions replace these lost copper ions, while preserving the shape of the original crystals. This simple two-step batch process represents an energy-efficient, cost-efficient, and versatile strategy to create materials with lower defect density and superior performance. The resulting new semiconductor could be used for advanced solar cells and thermoelectrics.
Contact
Pierre F. P. Poudeu
University of Michigan
[email protected]
Funding
This work was supported by the DOE Office of Science (Office of Basic Energy Sciences).
Publications
N. Moroz, A. Olvera, G. Willis, and P.F.P. Poudeu, “Rapid direct conversion of Cu2-xSe to CuAgSe nanoplatelets via ions exchange reactions at room temperature.” Nanoscale 7, 9452 (2015). [DOI: 10.1039/c5nr01451d].
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