Solar cell production method, and solar cell produced by same production method

摘要

This solar cell production method involves productively forming an antireflection film comprising silicon nitride, said antireflection film having an excellent passivation effect. In an embodiment, a remote plasma CVD is used to form a first silicon nitride film on a semiconductor substrate (102) using the plasma flow from a first plasma chamber (111), then to form a second silicon nitride film, which has a different composition than the first silicon nitride film, using the plasma flow from a second plasma chamber (112), into which ammonia gas and silane gas have been introduced at a different flow ratio than that of the first plasma chamber (111). The plasma chambers (111, 112) have excitation parts (111a, 112a) that excite the ammonia gas, and activation reaction parts (111b, 112b) and a flow controller (113).

主权项

1. A method for producing a solar cell having an antireflective film constructed of a first silicon nitride layer and a second silicon nitride layer having a composition different from the first silicon nitride layer on a surface of a semiconductor substrate, the method comprising:
providing a remote plasma-enhanced CVD apparatus including
a deposition compartment, anda first plasma compartment and a second plasma compartment each disposed above the deposition compartment in fluid communication with the deposition compartment, placing a substrate below a first plasma compartment in the deposition compartment, depositing a first silicon nitride layer on the semiconductor substrate from a first plasma flow from a first plasma compartment by generating a plasma flow of ammonia gas, introducing silane gas into the plasma flow and injecting the plasma flow toward the deposition compartment, conveying the substrate to below the second plasma compartment, and depositing a second silicon nitride layer of a different composition than the first silicon nitride layer from a second plasma flow from a second plasma compartment by generating a plasma flow of ammonia gas, introducing silane gas into the plasma flow and injecting the plasma flow toward the deposition compartment, the second plasma compartment having a different flow rate ratio of ammonia gas to silane gas than in the first plasma compartment, wherein each of the first and second plasma compartments is a cylindrical plasma-generating compartment comprising an excitation section for generating the plasma flow of ammonia gas fed from upstream and an activation reaction section disposed downstream of the excitation section for introducing silane gas into the plasma flow, and has end opening which is in fluid communication with the deposition compartment and injects the plasma flow toward the substrate placed below the end opening.