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Unformatted text preview: Increasing light energy 2.0 eV 2.5 eV 3.1 eV c o n d u c tio n b a n d (e m p ty ) v a le n c e b a n d (fil e d ) 1.7 eV LIGHT Solar Cell A Bandgap 1.0 eV 2.0 eV c o n d u c tio n b a n d (e m p ty ) v a le n c e b a n d (fil e d ) Solar Cell B Bandgap ENGRI 111 Homework #4 Due Monday, October 22, 2007 1. Solar cell A uses a semiconductor with a band gap of 1 eV. Solar cell B uses a semiconductor with a band gap of 2 eV. Either cell is thick enough to absorb all the light above its band gap. Both cells can work simultaneously with one on the top of the other to operate more efficiently in a small space. a) Which cell has to be on top (first to receive the sunlight) for both to work simultaneously, and b) why? There are, of course, two configurations for this problem: 1) Cell A on top and cell B on bottom 2) Cell B on top and cell A on bottom. Since either cell is thick enough to absorb all energies above its band gap, in order for both cells to work simultaneously, the second configuration must be used. Lets look at configuration 1 and see what would happen. Since the bandgap of cell As semiconductor is 1eV, it would absorb all energies (1.7-3.1eV) in the visible spectrum. No light would be transmitted through cell A and cell B would not generate...
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This note was uploaded on 02/28/2008 for the course ENGRI 1110 taught by Professor Giannelis during the Fall '07 term at Cornell University (Engineering School).
- Fall '07