Premium
Minimising bulk lifetime degradation during the processing of interdigitated back contact silicon solar cells
Author(s) -
Rahman Tasmiat,
To Alexander,
Pollard Michael E.,
Grant Nicholas E.,
Colwell Jack,
Payne David N.R.,
Murphy John D.,
Bagnall Darren M.,
Hoex Bram,
Boden Stuart A.
Publication year - 2018
Publication title -
progress in photovoltaics: research and applications
Language(s) - English
Resource type - Journals
SCImago Journal Rank - 2.286
H-Index - 131
eISSN - 1099-159X
pISSN - 1062-7995
DOI - 10.1002/pip.2928
Subject(s) - wafer , materials science , common emitter , silicon , solar cell , substrate (aquarium) , optoelectronics , doping , fabrication , evaporation , diffusion , crystalline silicon , nanotechnology , medicine , oceanography , alternative medicine , physics , pathology , thermodynamics , geology
In this work, we develop a fabrication process for an interdigitated back contact solar cell using BBr 3 diffusion to form the p + region and POCl 3 diffusion to form the n + regions. We use the industry standard technology computer‐aided design modelling package, Synopsys Sentaurus, to optimize the geometry of the device using doping profiles derived from electrochemical capacitance voltage measurements. Cells are fabricated using n ‐type float‐zone silicon substrates with an emitter fraction of 60%, with localized back surface field and contact holes. Key factors affecting cell performance are identified including the impact of e‐beam evaporation, dry etch damage, and bulk defects in the float zone silicon substrate. It is shown that a preoxidation treatment of the wafer can lead to a 2 ms improvement in bulk minority carrier lifetime at the cell level, resulting in a 4% absolute efficiency boost.