Abstract
The down-shifting (DS) process is a purely optical approach used to improve the short-wavelength response of a solar cell by shifting high-energy photons to the visible range, which can be more efficiently absorbed by the solar cell. In addition to the DS effect, coupling a DS layer to the top surface of a solar cell results in a change in surface reflectance. The two effects are intermixed and therefore, usually reported as a single effect. Here we propose a procedure to decouple the two effects. Analytical equations are derived to decouple the two effects, that consider the experimentally measured quantum efficiency of the solar cell with and without the DS layer, in addition to transfer matrix simulations of the parasitic absorption in the device structure. In this work, an overall degradation of 0.46 mA/cm2 is observed when adding a DS layer composed of silicon nanocrystals embedded in a quartz matrix to a silicon solar cell of 11% baseline efficiency. To fully understand the contribution from each effect, the surface reflectance and DS effects are decoupled and quantified using the described procedure. We observe an enhancement of 0.27 mA/cm2 in short-circuit current density due to the DS effect, while the surface reflectance effect leads to a degradation of 0.73 mA/cm2 in short-circuit current density.
Highlights
Down-conversion and down-shifting optical layers mounted on the top surface of solar cells can enhance the short-wavelength response of single-junction solar cells
The down-shifting (DS) process is a purely optical approach used to improve the short-wavelength response of a solar cell by shifting high-energy photons to the visible range, which can be more efficiently absorbed by the solar cell
An overall degradation of 0.46 mA/cm2 is observed when adding a DS layer composed of silicon nanocrystals embedded in a quartz matrix to a silicon solar cell of 11% baseline efficiency
Summary
Down-conversion and down-shifting optical layers mounted on the top surface of solar cells can enhance the short-wavelength response of single-junction solar cells. There are some limitations in these models such as not accounting for multiple reflections and interference in thin-film layers and ignoring the effects of parasitic absorption [5, 14, 15] These limitations can lead to an inaccurate evaluation of the DS conversion efficiency or the resulting internal quantum efficiency (IQE) of the solar cell with the DS layer, which is important in decoupling the surface reflectance and DS effects, as will be shown later. These lead to the individual contributions of surface reflection and DS effects to the short-circuit current density under AM1.5G spectrum.
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