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Anti-reflective coating A anti-reflective coating is deposited on the top side to help transmit more of the incident sunlight
Because the top side conductor has been already fabricated and only low temperature process can be used, the typical process to deposit anti-reflective coating is PECVD
PECVD P lasma E nhanced C hemical V apor D eposition PECVD is used extensively in the manufacture of microelectronic devices because it allows for lower temperature processes
Just like in sputtering, a plasma is formed in an electric field The plasma allows for the deposition or growth of films at lower temperature than would normally be required in just a CVD process
Trion ORION III PECVD tool
Typical PECVD Process The wafer is loaded in into the vacuum chamber The chamber is pumped to vacuum conditions The wafer is heated to deposition temperatures (300 o C typical) Gas are introduced that will acts as precursors to the film growth
Typical PECVD Process (continued) Chamber pressure is regulated to provide an equilibrium pressure ( gas in, pumping out) RF power is applied to the chamber creating a plasma A film is grown based on the gases introduced
For our solar cell We will be using SiO2 as the antireflective coating There are better anti-reflective coatings but not available in the Cameron clean room such as SiN or ITO
Trion ORION III PECVD Chamber lid open Heated substrate stage Can accommodate up to 8” wafers
Trion ORION III water chiller and dry (no oil) chemical vacuum pump
Trion ORION III process gas cabinet TEOS (tetraethylorthosilicon) SiO 2 precursor
The blue tint to the solar cell is the anti-reflective coating