I was trying to google out these things. That is what I found to specific questions.
1.
For crystalline silicon the energy gap Eg = 1.12 eV.
For amorphous silicon the energy gap Eg = 1.75 eV
The situation is very lossy for crystalline silicon as it is an indirect band gap material. Amorphous silicon is however a direct band gap material.
For wavelengths longer than the critical value c, the photon energy is no longer sufficient to excite electrons to the conduction band and the material becomes transparent to those wavelengths.
Amorphous silicon has a higher band gap (1.75 eV) than crystalline silicon (c-Si) (1.12 eV), which means it absorbs the visible part of the solar spectrum more strongly than the infrared portion of the spectrum. a-Si:H In early studies of amorphous silicon, a-Si, it was determined that plasma-deposited amorphous silicon contained a significant percentage of hydrogen atoms within the amorphous silicon structure. These atoms were discovered to be essential to the improvement of the electronic properties of the material.
but Im not sure does it cover the problem
2.
The I–V characteristic of an ideal diode in either forward, reverse bias or zero bias are expressed by [exp( ) 1] 0 k T qV I I diode Where: Idiode is the diode current Io is the reverse bias saturation current V is the voltage across the diode k is Boltzmann’s constant 1.380 ×10−23 JK −1 q is the charge on an electron 1.6 ×10−19 C In the absence of light, the I-V characteristics of a solar cell are also expressed by the Schockley Equation: [exp( ) 1] 0 k T qV I I diode Io I V When light is absorbed and photo current generated, Iphoto, the output current is represented by I – this is simply expressed as the difference between the photocurrent, Iphoto and the diode current, Idiode I = Iphoto - Idiode [exp( ) 1] 0 k T qV I I I photo
I couldn't found the better specification
3.
The current generated is proportional to the incident light or radiation power. The light is absorbed exponentially with distance and is proportional to the absorption coefficient. The absorption coefficient is very high for shorter wavelengths in the UV region and is small for longer wavelengths Hence, short wavelength photons such as UV, are absorbed in a thin top surface layer while silicon becomes transparent to light wavelengths longer than 1200 nm. Moreover, photons with energies smaller than the band gap are not absorbed at all.
4.
Amorphous silicon has a higher band gap (1.75 eV) than crystalline silicon (c-Si) (1.12 eV), which means it absorbs the visible part of the solar spectrum more strongly than the infrared portion of the spectrum. a-Si:H In early studies of amorphous silicon, a-Si, it was determined that plasma-deposited amorphous silicon contained a significant percentage of hydrogen atoms within the amorphous silicon structure. These atoms were discovered to be essential to the improvement of the electronic properties of the material.
5.
• the number of photons absorbed by the cell
• the electron charge
• the quantum efficiency
• the photon wavelength
• the surface area
not sure whether these are relevant factors
6.
Trying to describe the meaning of factors from previous question.
I need the verification of my answers. If any ambiguities or mistakes please give me the hints or send me the links to websites where could I find out more. I'll be grateful for your assistance