Abstract
The production and performance of p‐type inversion layer (IL) Si solar cells, manufactured with an ion‐injection technique that produces a highly charged dielectric nanolayer, are investigated. It is demonstrated that the field‐induced electron layer underneath the dielectric can reach a dark sheet resistance of 0.95 kΩ sq−1 on a 1 Ω cm n‐type substrate, lower than any previously reported. In addition, it is shown that the implied open‐circuit voltage of a p‐type IL cell precursor with a highly charged dielectric is equivalent to that of a cell with a phosphorous emitter. In the cell precursor, light‐beam‐induced current measurements are performed, and the uniformity and performance of the IL is demonstrated. Finally, simulations are used to explain the physical characteristics of the interface leading to extremely low sheet resistances, and to assess the efficiency potential of IL cells. IL cells are predicted to reach an efficiency of 24.5%, and 24.8% on 5/10 Ω cm substrates, by replacing the phosphorous emitter with a simpler manufacturing process. This requires a charge density of beyond 2 × 1013 cm−2, as is demonstrated here. Moreover, IL cells perform even better at higher charge densities and when negative charge is optimized at the rear dielectric.
Highlights
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This work studies the fabrication and potential of p-type inversion layer (IL) Si solar cell based on highly charged dielectric nanolayers
The ionic charge was applied to a p-type substrate with laserdoped selective emitters to fabricate a precursor cell, with its implied Voc exceeding 600 mV after induction of the IL
Summary
Two sets of silicon specimens were used here. The first set was used to optimize the dielectric charge and understand the properties of a SiO2/Si interface, whereas the second set was used to manufacture IL cell precursors and test the characteristics of the cell. Processing method for field- and temperature-assisted migration of ions into surface dielectrics: delivery of ion precursor, applying a polarization electric field, and annealing. Considering there is no illumination, ∫ σðBÞdt is close to ∫ σðB0Þdt, and ∫ σðA0Þdt
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