Project overview
Almost the whole of modern technology and life is underpinned by methods for depositing and shaping materials. For instance the transistors which power our mobile phones, tablets, etc. consist of areas of silicon whose dimensions are now of the order of only tens of atoms across. Whilst current materials deposition technologies are truly impressive, there is still a need for more innovative, better and reduced cost methods for depositing technologically important materials in order to increase energy efficiency, improve their functional properties and break through into potential new markets. This is particularly true when we consider materials beyond the narrow range of those used in electronics and telecoms. A clear example of this is in the field of thermoelectric materials which can already be used in devices such as refrigerators, but more importantly in generating electricity directly from waste heat. Fundamental science has shown that if we could produce such materials in the form of dense parallel arrays of ultrathin wires that are each only 10-100 atoms across, the efficiency of these devices would be massively enhanced. However, the technology to achieve the necessary high quality materials at this size scale does not currently exist. In the field of computer memory, materials whose electrical resistances can be altered by rapid heating and cooling, so called phase change materials, are being developed The key barriers to the wide spread application of these materials are their relatively high switching energy and reliability of many billions of switching cycles. These could be overcome if a materials deposition technique existed which allowed us to deposit smaller elements than can currently be achieved. Finally the materials that are used in heat, i.e. infrared, sensing cameras could have a much wider range of applications, e.g. in home security and short range communications between smart appliances, if the cost of depositing them wasn't so high. This project will directly address these challenges, by building upon our recent breakthroughs in using electrodeposition, in which an electrical current causes the deposition of a material, from unusual, 'weakly-coordinating' solvents, to develop methods for depositing high quality materials for advanced applications in the fields of thermoelectric devices, phase change memory and infrared sensors and cameras.
Staff
Lead researchers
Other researchers
Collaborating research institutes, centres and groups
Research outputs
Rhys, Paul King, Madeleine, Serena Woodward, Julian Grigg, Graeme McRobbie, William Levason & Gillian Reid,
2021, Dalton Transactions, 50(40), 14400-14410
DOI: 10.1039/D1DT02948G
Type: article
Yasir Noori, Lingcong Meng, Ayoub Hassan Jaafar Hamdiyah, Wenjian Zhang, Gabriela Kissling, Yisong Han, Nema Abdelazim, Mehrdad Alibouri, Kathleen Leblanc, Nikolay Zhelev, Ruomeng Huang, Richard Beanland, David C. Smith, Gillian Reid, Kees De Groot & Philip N. Bartlett,
2021, ACS Applied Electronic Materials, 3(8), 3610-3618
Type: article
Rhys, Paul King, Victoria Greenacre, William Levason, John Dyke & Gillian Reid,
2021, Inorganic Chemistry, 60(16), 12100–12108
Type: article
Liam Mcdonnell, Jacob Viner, David Ruiz-Tijerina , Pasqual Rivera , Xiaodong Xu, Vladimir Fal'ko & David C. Smith,
2021, 2D Materials, 8(3)
Type: article
Yasir Noori, Nema Abdelazim, Shibin Thomas, Victoria Greenacre, Yisong Han, Danielle E. Smith, Giacomo M Piana, Nikolay Zhelev, Andrew L. Hector, Richard Beanland, Gillian Reid, Philip N. Bartlett & Kees De Groot,
2021, Advanced Electronic Materials, 7(9), 1-8
Type: article
Yasir Noori, Shibin Thomas, Sami Ramadan, Danielle E. Smith, Victoria Greenacre, Nema Abdelazim, Yisong Han, Richard Beanland, Andrew L. Hector, Norbet Klein, Gillian Reid, Philip N. Bartlett & Kees De Groot,
2020, ACS Applied Materials and Interfaces, 12(44), 49786-49794
Type: article
Simon Reeves, Yasir Noori, Wenjian Zhang, Gillian Reid & Philip N. Bartlett,
2020, Electrochimica Acta, 354
Type: article