Solar

Question 1

List the advantages and disadvantages of using photovoltaic (PV) solar cells relative to forms of energy generation utilising fossil fuels.

Answer 1

AD – sustainable electricity no CO2

• Long life, very low maintenance
• noise and pollution free
• modular power source mW to MW
• high level of public acceptance
• only renewable that is suitable for urban environment
• energy payback of 0.5 to 4 years

DIS – PV cannot operate without light

• high initial costs that over shadow the low maintenance costs
• large area needed
• PV generated direct current so inverters are needed
• energy storage is usually needed in off grid applications

Question 2

Three common types of PV solar cells are: crystalline-Si, Cd-Te and CIGS. Describe how these different types of PV solar cell material are produced.

Answer 2

• crystalline-Si: produced by Czochralski growth of float zone – both are expensive
• Cd-Te: thon film deposition techniques – uses toxic materials so need to consider end of life safety, efficiency has been increasing in the last 5 years
• CIGS: co-evaporation or sputtering process, expensive technique and same effeicey as Cd-Te

Question 3

Define what is meant by the band gap of a material. Briefly describe the importance of the band gap, in relation to a PV solar cell material

Answer 3

• the band gap is the energy required to free an outer shell electron from its orbit to become a mobile charge carrier
• PV materials rely on illumination for added energy to cause electrons to jump the band-gap. When a photon is absorbed by the material and an electron jumps the fap to the conduction band, an electron-hole pair is formed

Question 4

Explain how a PV “tandem” solar cell, may achieve a higher overall efficiency.

Answer 4

• efficiency of solar cells can be increased by stacking several cells with different bandgaps so that the gap energy decreases from the top
• the top cells absorbed high energy photons and bottom cells low energy photos so each cells converts part of solar spectrum at max efficiency

Question 5

What are intrinsic and extrinsic semiconductors

Answer 5

• Intrinsic: thermal energy excites electrons from valence to conduction band
• Extrinsic: elements are added that create holes or electrons

Question 6

Outline the major materials challenges associated with Concentrated Solar Power (CSP) systems.

Answer 6

• Thermochemical fatigue
• thermal shock if temporary blockage which damages some section of piping
• overheating
• creep
• hot corrosion
• erosion
• stress corrosion cracking
• solidification of molten salts
• combustion of oil

Question 7

Bulk heterojunction organic PV solar cells can be formed by combining a C60-derivative, with a type of conducting polymer. Describe how these two components are usually mixed and discuss the important attributes of the resulting microstructure.

Answer 7

• 2 components are dissolved in a solvent and spin-coated onto a transparent conductive polymer which is on top of ITO – conducting glass
• if exciton reaches the interface with the fullerene, an electron is transferred to the fullerene phase creating an electron-hole pair
• electrons are collected at the ITO anode by transport through the fullerene phase and the holes are collected at the AI cathode by the transport through the polymer phase.

Question 8

Describe the constituent components of a typical Dye Sensitized Solar Cell (DSSC). Outline the operating principles of a DSSC.

Answer 8

• thin porous layer of mesoporous titania coated with a monolayer of red ruthenium bipridyl complex which acts as a highly efficient light harvesting material
• electrons injected into the Titania film diffuse to the FTO contact where they are transferred to the external circuit

Question 9

List 4 out of the main types of Concentrated Solar Power (CSP) system.

Answer 9

• parabolic trough: used to be most common
• solar dish: most efficient
• concentrating linear Fresnel reflector
• solar chimney
• solar power tower