Annealing of Silicon Heterojunction Solar Cells: Interplay of Solar Cell and Indium Tin Oxide Properties

In this paper, we report the evolution of silicon heterojunction solar cell properties focusing, in particular, on the indium tin oxide (ITO) layers upon consecutive thermal annealing. We find that the charge carrier density $N_{\rm e}$ of the ITO increases with higher thermal budget, while the carrier mobility remains constant. For the solar cells, their series resistance at the maximum power point $R_{\rm S}^{\rm MPP}$ first decreases due to the reduction of the ITO’s sheet resistance. With further annealing, $R_{\rm S}^{\rm MPP}$ increases again. As all monitored $R_{\rm S}$ components decrease, we attribute this to an increase of the contact resistance. The implied $V_{\text{OC}}$ and the implied fill factor both slightly degrade for annealing temperatures above 190 °C for our layers. This, as well as the change in $N_{\rm e}$ of the ITO, must be carefully considered when optimizing the thermal budget needed, e.g., for sputter damage or screen-printing paste curing.


Published in:
IEEE Journal of Photovoltaics, [Early Access], 1-6
Year:
Jul 24 2019
Other identifiers:
Laboratories:




 Record created 2019-08-14, last modified 2019-08-15

Final:
Download fulltext
PDF

Rate this document:

Rate this document:
1
2
3
 
(Not yet reviewed)