Making use of solar energy efficiently is critical to achieve Net Zero goals while simultaneously meeting ever increasing global energy demands. The main current technology utilised are solar photovoltaics (PVs), mostly based on silicon, which can convert around 25% of incident sunlight into electrical power. There are new PV technologies and materials being developed, but all are based on semiconductor junctions, and are therefore limited to a maximum theoretical efficiency of around 34% for any single junction. At the same time, to address intermittency issues with solar energy, and also provide low-cost, renewable fuel replacements, exciting routes to produce hydrogen or hydrocarbons directly from sunlight and water or CO2 are being developed using photocatalytic solar fuel generation. However, large advances are needed to make this technology viable, and it is limited by similar maximum theoretical efficiencies.
At the same time, a class of materials known as ferroelectrics can also convert sunlight to electricity (or fuels in photocatalytic processes). They utilise a fundamentally different mechanism to do this, known as the bulk photovoltaic effect (BPVE). However, despite many efforts to improve their efficiency, it generally lies well below 1%. One challenge is that most ferroelectrics are not able to absorb most visible light. More fundamentally, the underlying mechanism of the BPVE is also limited, potentially to even lower maximum efficiencies than conventional junction-based PVs.
In this project we take an innovative approach to overcome these dual efficiency limits. We draw on the proven ability for ferroelectrics to interact strongly with the semiconductors used in PVs and photocatalysts. As this interaction only occurs at the very small scale (on the order of nanometers), we are producing ‘nanocomposites’ of ferroelectrics and semiconductors to maximise the interactions. In these nanocomposites, the semiconductors absorb the light, and the high voltages generated by the ferroelectrics are used to drive a resulting photocurrent in the semiconductor. In this way we will demonstrate a new mechanism to generate electricity and fuels from solar energy. This has previously unexplored efficiency limits, and we will study the underlying science behind the effects to understand these and optimise the materials and devices. Therefore, the overall objectives are to:
1. Design and synthesise optimal ferroelectric nanostructures and gain control over their properties, including the BPVE, through careful study and tuning of the material properties in both precision model systems and low-cost materials;
2. Develop detailed device models to accurately describe and predict the behaviour of these novel devices, incorporating progressive knowledge and understanding throughout the project using both empirical data and computational modelling;
3. Use these models to predict the optimum materials, structures and designs to demonstrate this novel technology and optimise device performance;
4. Fabricate and test proof-of-concept devices based on these optimised designs to validate the models and prove the hypothesis, establishing a new frontier in solar energy generation and wider science.
Through this, the project will set out a new route to solar energy conversion that could lead to technologies in future that can convert solar energy to electricity or fuels at much higher efficiencies, thus accelerating the deployment of solar energy technologies.
