Feasibility study of growth by MBE of As doped GaN layers for photoanode applications in hydrogen production by photoelectrochemical water splitting

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Title
Feasibility study of growth by MBE of As doped GaN layers for photoanode applications in hydrogen production by photoelectrochemical water splitting

CoPED ID
088ef872-0795-4747-8254-3bc07e90c1a7

Status
Closed

Funders

Value
£87,490

Start Date
Aug. 31, 2008

End Date
Aug. 30, 2009

Description

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The move towards low carbon solutions for our energy supply is probably one of the most important aims for our society. The potential solutions include the use of hydro energy, biomass energy, solar energy, wind energy and geothermal energy.Currently there are two main methods to transport energy from the primary source where it is produced to the place where it is needed - electricity and heat. However, in future new methods may become dominant. One of the most promising carriers is hydrogen (H2), which can be generated by water splitting and can be easily converted into electricity and heat by means of fuel cells.Photoelectrochemical (PEC) cells, illuminated by sunlight, have the ability to split water into hydrogen and oxygen. Such cells generate electronic charge at the surface of a photoelectrode subjected to solar radiation. The choice of material for the photoanode (photocathode) is crucial for efficient hydrogen production using the PEC method. Semiconductor materials used for photoanodes require the proper band gap. The band gap must be in the ideal range of the solar spectrum to absorb photons. In addition to choosing the correct band gap, the conduction and valence band edges need to be aligned to the water splitting redox potentials. Therefore, the ideal band gap is around ~2.0eV. The second requirement is for the photoanode material to be corrosion-resistant in water solutions for long periods of operation. In compound semiconductors the above requirements point towards group III/nitrides. Gallium nitride (GaN) has a band gap ~3.4eV, high mechanical hardness and high chemical stability. The band gap of GaN can be adjusted and decreased due to strong negative bowing in the GaN-based solid solutions with group V elements. Hydrogen fuel cells are the subject of a massive Department of Energy (DOE) programme in the USA during the last few years. One of the groups involved in this programme is based at the Lawrence Berkeley National Laboratory. Theoretical calculations performed there by Prof. Walukiewicz suggest that the GaN1-xAsx material system is one of the most promising materials for the photoanodes. However, a large miscibility gap was theoretically predicted and experimentally confirmed for the Ga-N-As system. The highest concentrations reported so far in GaN1-xAsx layers is x~1%. At the University of Nottingham, our group has studied extensively growth by molecular beam epitaxy (MBE) of GaN-based solid solutions for more than a decade. We have studied in great detail the growth and properties of GaN1-xAsx layers prepared by MBE, using a plasma source for active nitrogen. As a result of our expertise in this area, we have been approached by Prof. W. Walukiewicz with a request for GaN1-xAsx material for photoanodes applications in PEC cells for hydrogen production. Even though we have spent a lot of effort studying the growth of this material system, the particular requirements for the photoanode material are significantly different from our previous applications. We need to investigate significantly different MBE growth conditions in order to satisfy the requirements for the higher As content needed in the PEC photoanode application and indeed to determine if this requirement can be met. Therefore, we are applying for a short feasibility study of the growth by MBE of GaN1-xAsx with a high As content (0.05

Sergei Novikov PI_PER
Richard Campion COI_PER
Charles Foxon COI_PER
Anthony Kent COI_PER

Subjects by relevance
  1. Hydrogen
  2. Renewable energy sources
  3. Semiconductors
  4. Fuels

Extracted key phrases
  1. Short feasibility study
  2. Different MBE growth condition
  3. PEC photoanode application
  4. Photoanode material
  5. XAsx material system
  6. Ideal band gap
  7. Hydrogen fuel cell
  8. Proper band gap
  9. Band gap ~3.4eV
  10. Correct band gap
  11. Efficient hydrogen production
  12. Water solution
  13. Solar energy
  14. GaN layer
  15. Energy supply

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