Understanding the role of mesoporous Silicon in sustainable energy applications

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Title
Understanding the role of mesoporous Silicon in sustainable energy applications

CoPED ID
58d23414-bb8a-4791-bb57-8bfa16869797

Status
Closed


Value
£51,150

Start Date
May 31, 2021

End Date
May 31, 2022

Description

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EPSRC : Maximilian Yan : EP/L016818/1

Lithium-ion batteries are the battery of choice in power-hungry applications such as grid energy storage and electric cars. However, certain characteristics of this battery, including its energy density, limits the performance of the devices they are used in. For example, a full tank of petrol weighing 45 kg will give a range of 300 miles, whereas a battery will have to weigh more than 450 kg, which is why electric vehicles tend to have much lower mileage. Silicon is a material capable of storing more than ten times the energy of the currently used graphite, however, for any material to reach commercialisation it has to be manufactured at large scales. Hence, it is crucial that a material not only performs well, but can be produced in a cost-effective, sustainable manner that can easily be scaled up.

By combining our material with the process developed in Dr Dasog's group in Canada, we will be able to better understand the reaction chemistry of the energy efficient, low-temperature magnesiothermic reduction process. This will allow us to make optimisations to improve its viability for scale-up. This project will also include a modelling aspect, whereby the results from experiments will be fed into a techno-economic model, which can be used as a tool for battery manufacturers to determine the best type of silica feedstock and reduction conditions for a chosen application. As the procedure for manufacturing porous silicon is the same, the techno-economic model can be expanded to include a cost analysis for photocatalytic applications. The cost of producing porous silicon for this application can be calculated based on a given performance metric and therefore its value, using data already collected from magnesiothermic reduction experiment.

Subjects by relevance
  1. Accumulators
  2. Energy efficiency
  3. Silicone
  4. Lithium-ion batteries
  5. Optimisation
  6. Electric cars
  7. Emissions
  8. Silicon
  9. Batteries

Extracted key phrases
  1. Sustainable energy application
  2. Grid energy storage
  3. Energy efficient
  4. Energy density
  5. Hungry application
  6. Photocatalytic application
  7. Ion battery
  8. Mesoporous Silicon
  9. Battery manufacturer
  10. Temperature magnesiothermic reduction process
  11. Maximilian Yan
  12. Sustainable manner
  13. Material capable
  14. Magnesiothermic reduction experiment
  15. Porous silicon

Related Pages

UKRI project entry

UK Project Locations