Solar Panel Bandgap

Put in terms of radiation all the photons in the visible spectrum are strong enough to causeelectrons to jump the band gap.

Solar panel bandgap. While you can use solar panel trackers to keep them at the optimum angle at all times the costs and complications involved aren t worth it in most cases. Solar cells made from cadmium telluride cdte the bandgap energy is 1 44 ev. Sunlight photons with less than the band gap energy will simply pass through the solar cell. Research in cdte dates back to the 1950s because its band gap 1 5 ev is almost a perfect match to the distribution of photons in the solar spectrum in terms of conversion to electricity.

For solar cells made from silicon to provide pv electricity the photons which hit a solar cell must have energy greater than 1 11 ev. Therefore the best angle for your solar panels is the one that allows the panels to get the most direct perpendicular light. The most efficient bandgap is found to be at 1 34 ev with a maximum power conversion efficiency pce of 33 7. A simple heterojunction design evolved in which p type cdte was matched with n type cadmium sulfide cds.

Dowlinga adepartment of physics and astronomy hearne institute for theoretical physics louisiana state university 202 nicholson hall. This first calculation used the 6000k black body spectrum as an approximation to the solar spectrum. Traditional single junction cells with an optimal band gap for the solar spectrum have a maximum theoretical efficiency of 33 16 the shockley queisser limit. Ideal solar band gaps crystalline silicon the most popular solar cell semiconductor has a bandgap of 1 1 electron volts ev.

Solar cells with multiple band gap absorber materials improve efficiency by dividing the solar spectrum into smaller bins where the thermodynamic efficiency limit is higher for each bin. Solar panels produce electricity when sunlight hits their surface and they produce the most energy when that sunlight is exactly perpendicular to the panel face. Solar energy materials solar cells 91 2007 1599 1610 improving solar cell efficiency using photonic band gap materials marian florescua b hwang leea irina puscasuc martin prallec lucia florescua b david z. Reaching this ideal bandgap energy can be difficult but utilizing tunable perovskite solar cells allows for the flexibility to match this value.

The semiconductor chosen for a solar cell has to absorb as much of the solar spectrum as possible therefore a low band gap is desireable. Subsequent calculations have used measured global solar spectra am1 5g and included a back surface mirror which increases the maximum efficiency to 33 7 for a solar cell with a bandgap of 1 34 ev.