Research project

G Reid - Selective Chemical Vapour Deposition

Project overview

Thermoelectric micro-generators are solid state devices that can provide constant sources of electricity. They have a number of very favourable features, i.e. no mechanical parts that can wear out, require little maintenance, have long lifetimes and produce no emissions. Solid-state thermoelectric devices are based upon one of two phenomena, the Seebeck effect, which can be used for power generation (energy harvesting), and the Peltier effect for electronic cooling or heating. In order to produce a functional thermoelectric device, an n-type doped material is connected electrically in series and thermally in parallel across a temperature differential to a p-type doped material, so that current flows between the two. Bismuth telluride based thermoelectric materials are very well suited for near room temperature applications, including wireless sensing. Through recent research supported by STFC, we have developed a new series of molecular precursor compounds which can be used in chemical vapour deposition to produce high quality thin films of (n-type) bismuth telluride and (p-type) antimony telluride. Unusually, our precursors and CVD-based system allows the materials to be deposited very selectively onto specific areas of lithographically patterned substrates. The focus of this project is to work closely with key stakeholders, including a thermoelectric device company and a specialist precursor manufacturer, to exploit the unique features of our precursors and CVD-based approach so that the production costs for manufacture of thermoelectric micro-generators can be reduced significantly. Since the actual production costs account for the majority of the unit cost per thermoelectric generator, reducing this is a high priority to allow penetration of these micro-generator devices into new and larger markets.

Staff

Lead researchers

Professor Gill Reid

PROFESSOR OF CHEMISTRY

Research interests

  • Synthetic inorganic chemistry
  • Design and synthesis of new macrocyclic and multidentate ligands involving donor atoms from Groups 15 (P, As, Sb, Bi) and 16 (S, Se, Te)
  • Coordination chemistry with s-, p-, d- and f-block metal ions
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Other researchers

Professor Andrew Hector

Head of School

Research interests

  • Materials synthesis, including metal nitrides, thin film materials, sol-gel and solvothermal processes and porous structures.
  • Materials characterisation – powder and thin film diffraction, microscopy and spectroscopy techniques.
  • Electrochemistry, including charge storage in battery and supercapacitor type cells, and electrodeposition of various materials. 
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Professor Kees De Groot

Professor

Research interests

  • Radio-Frequency and Microwave Devices
  • 2 dimensional Transition Metal Dichalcogenides  Transistors
  • Smart Radiative Cooling and RF control of smart glass using metal oxides such as Al-doped ZnO and W-doped VO2
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Research outputs

Samantha, Louise Hawken, Ruomeng Huang, Cornelis De Groot, Andrew L. Hector, Marek Jura, William Levason & G.B.G. Stenning, 2019, Dalton Transactions, 48, 117-124
Type: article
Sophie Benjamin, Cornelis De Groot, Chitra Gurnani, Samantha, Louise Hawken, Andrew L. Hector, Ruomeng Huang, Marek Jura, William Levason, Eleanor Reid, Gillian Reid, Stephen Richards & Gavin B.G. Stenning, 2018, Journal of Materials Chemistry C, 6(29), 7734-7739
Type: article