Abstract
Fully exploiting the power conversion efficiency limit of silicon solar cells requires the use of passivating contacts that minimize electrical losses at metal/silicon interfaces. An efficient hole-selective passivating contact remains one of the key challenges for this technology to be deployed industrially and to pave the way for adoption in tandem configurations. Here, we report the first account of silicon nitride (SiNx) nanolayers with electronic properties suitable for effective hole-selective contacts. We use x-ray photoemission methods to investigate ultra-thin SiNx grown via atomic layer deposition, and we find that the band alignment determined at the SiNx/Si interface favors hole transport. A band offset ratio, ΔEC/ΔEV, of 1.62 ± 0.24 is found at the SiNx/Si interface for the as-grown films. This equates to a 500-fold increase in tunneling selectivity for holes over electrons, for a film thickness of 3 nm. However, the thickness of such films increases by 2 Å–5 Å within 48 h in cleanroom conditions, which leads to a reduction in hole-selectivity. X-ray photoelectron spectroscopy depth profiling has shown this film growth to be linked to oxidation, and furthermore, it alters the ΔEC/ΔEV ratio to 1.22 ± 0.18. The SiNx/Si interface band alignment makes SiNx nanolayers a promising architecture to achieve widely sought hole-selective passivating contacts for high efficiency silicon solar cells.
Highlights
The need for renewable energy sources is ever increasing due to the immense pressure put on reserves of fossil fuels by our growing energy demands, as well as the environmental detriment from using these non-renewable counterparts
Exploiting the power conversion efficiency limit of silicon solar cells requires the use of passivating contacts that minimize electrical losses at metal/silicon interfaces
We use x-ray photoemission methods to investigate ultrathin SiNx grown via atomic layer deposition, and we find that the band alignment determined at the SiNx/Si interface favors hole transport
Summary
The need for renewable energy sources is ever increasing due to the immense pressure put on reserves of fossil fuels by our growing energy demands, as well as the environmental detriment from using these non-renewable counterparts. Among all renewable energy sources, photovoltaic (PV) technologies have shown great promise toward tackling such demands This is primarily due to the abundance of solar energy and the rapid development and deployment of such technologies.[1,2] Currently, crystalline silicon comprises over 90% of the market share, and the PV community continues to strive toward reaching the power conversion efficiency (PCE) limit of this technology.[1] The bulk of this market is dominated by architectures that suffer from high electrical losses at the metal–Si interface, limiting these technologies to PCEs considerably lower than the theoretical limit of 29.4%.3,4. Beyond the work reported here, full deployment as hole-selective passivating contacts still requires maintaining superior Si surface passivation with such ultra-thin films, relative to its non-passivating counterparts
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