UK researchers in London and Bristol have won a £1 million grant to develop high-performance compound semiconductor solar cells based on self-organized quantum-dot structures.
Principal investigator Huiyun Liu and Alwyn Seeds, head of the photonics group at University College London (UCL), are set to receive just over £600,000 to develop a deposition process to fabricate the cells on silicon substrates, while a team at the University of Bristol will contribute device modeling and characterization expertise.
Funded by the EPSRC, the project aims to combine the extremely high photovoltaic conversion efficiencies possible using multi-junction III-V devices with cheap production on silicon wafers.
At present, commercial multi-junction solar cells tend to be fabricated on relatively expensive germanium or gallium arsenide wafers, using precision deposition equipment that is far slower than the tools used to make conventional but far less efficient silicon cells.
The UCL researchers will grow the structures using the molecular beam epitaxy facility within the department, with device fabrication taking place at the LCN.
The thinking behind the use of a silicon substrate follows a similar trend already evident in the manufacture of high-brightness LEDs, where large companies such as Osram, Samsung and Epistar are all working on structures that combine the excellent photonic properties of compound semiconductors with the volume manufacturability of silicon.
Along with the likes of UK-based Plessey Semiconductors and California’s Bridgelux, they have all developed some form of “barrier” layer that compensates for the lattice and thermal mismatch between the silicon and compound semiconductor materials, something that can be highly detrimental to device performance.
But a similar approach to make the high-efficiency solar cells that are typically used to power satellites and in concentrated photovoltaics (CPV) applications has not yet reached any level of commercialization.