Theoretical insight into the enhancement of longer-wavelength light absorption in silicon solar cell with multilevel impurities

TL;DR

This paper theoretically demonstrates that introducing multilevel impurities in silicon solar cells enhances long-wavelength light absorption, leading to increased efficiency through impurity-assisted photon upconversion.

Contribution

It presents a novel theoretical design of silicon solar cells with multilevel impurities that significantly improve light absorption and efficiency.

Findings

PCE increased from 25.4% to 35.4% with impurities

Short circuit current improved by 3.76 mA/cm2

Enhanced long-wavelength absorption via impurity-assisted photon upconversion

Abstract

In this article, we theoretically demonstrate multilevel impurity photovoltaic effect in an efficient silicon dual-homojunction solar cell that ensures an extended absorption of longer wavelength light. Along with suitable contact work functions (Ni and Ta as anode and cathode, respectively), three impurity energy levels from acceptor type impurities (One from Tl and two from Zn) have been introduced in the energy gap of the absorber layer in the solar cell. The pristine Si solar cell shows a PCE of 25.4% with JSC= 37.99 mA/cm2, VOC=0.780V and FF=85.76%, respectively. The incorporation of Tl impurity level alone provides a PCE of 33.4%, with JSC= 51.56 mA/cm2, VOC=0.789 V and FF=82.03%, respectively. The PCE of the solar cell further enhances to 35.4% with a further enhancement of the short circuit current by 3.76 mA/cm2 due to the inclusion of Zn impurity into the optimized structure. This enhancement of the JSC and hence PCE is resulted from the longer wavelength light absorption due to impurity-assisted two-step photon upconversion in the solar cell.