LYDIA WONGlab

Emerging Photovoltaic Technology

Development of efficient solar cell devices for harvesting solar energy poses a significant challenge due to a range of issues, including and not limited to defects states, film quality, reproducability, band alignment, stability and cost for production. We hope to control the properties of solar harvesting materials to create reproducible devices suitable for industrial scale-up and large-area applications, with the aim of cheap, high efficiency, robust solar cell devices. An example of such a device would be for semi-transparent window applications, where the lifetime and reproducability of these large scale devices are key to it's everyday use.

Our group thus focuses on three separate classes of materials: perovskite solar cells, Cu2ZnSnS4 (CZTS), and Sb2(S, Se)3. In these materials, we seek to understand how to control the distribution of intrinsic defects such as antisite defects, grain orientation and grain boundaries to achieve higher efficiency. Our work thus far has shown capabilities in controlling the properties by doping and substitution of various ions, notably in triple cation perovskites [2] and substituted CZTS materials [3] [4] [5] where the cation exchange allows for suppression of antisite defects whilst retaining or improving its original properties. Additionally, strategies in device fabrication, such as substrate choice and thus device architecture and optimising growth processes, have led to perovskite [6] and Sb2(S, Se)3 solar cells [7] with increased quality.

Materials for Solar Fuel Generation

There is also interest in clean, green fuel generation as an alternative to renewable energy sources. Interest in this derives from two aspects: first to allow for carbon sequestration by converting carbon dioxide into reusable fuels such as carbon monoxide (for syngas), formic acid, methanol and multicarbon products, and secondly to facilitate lower emissions in sectors which are less easily electrified, such as transport and aviation. Both the carbon dioxide reduction and hydrogen evolution reaction occur in-tandem with the oxygen evolution reaction. These reactions can be mediated by either electricity from renewable sources (electrochemical) or by utilising the solar spectrum itself (photoelectrochemical).

Selective, long-lasting catalysts remains as the major barrier to large-scale applications of the carbon dioxide reduction reaction. This is because there remains a poor understanding in the mechanisms of the carbon dioxide reduction reaction, thus leading to difficulties in catalyst design. In particular, catalysts need to facilitate sufficient binding of the reactants but have a weaker binding energy with the products of interest, thus allowing only specific products to be produced (hence high selectivity). Our group is currently interested in several potential catalysts, such as bimetallic copper chalcogenides and single atom catalyststs, where the combination of atoms allow for tuning the binding energies and thus the selectivity and rate of reaction.

Photoelectrochemical water splitting for hydrogen generation also holds much interest as the reaction mechanism is broadly dictated by the band alignment of the photocathode with the solution. Water splitting only proceeds if the band edge of the photocathode is high enough to overcome the overpotential necessary for the reaction to proceed, limiting the photocathode choice. This issue is further compounded with possible degradation, whether due to photon or immersion of the photocathode in water or acidic media. Our group is interested in optimising device composition and structures of CZTS [8] [9] and Sb2Se3 photocathodes to allow for efficient capture of the solar spectrum and charge transport to the solution.

The oxygen evolution reaction faces issues shared by both the carbon dioxide reduction and hydrogen evolution reaction, where there is concern in catalyst discovery to allow for the 4-electron transfer in the oxygen evolution whilst still allowing for efficient charge transport by ensuring the band alignment of the device is suitable for the reaction mechanism. This is further complicated by potential catalysts-photoanode interaction that may change the energetics of the reaction [10] . Numerous methodologies have been employed in order to optimise the photoanode performance [11] . We currently focus on binary metal oxides for photoanodes and seek to optimise its composition using high throughput screening.