Thermal emissivity of silicon heterojunction solar cells

Thermal emissivity of silicon heterojunction solar cells

The aim of this work is to evaluate whether silicon heterojunction solar cells, lacking highly emissive, heavily doped silicon layers, could be better candidates for hybrid photovoltaic thermal collectors than standard aluminium-diffused back contact solar cells. To this end, the near and mid infrar...

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Bibliographic Details
Published in:Solar energy materials and solar cells Vol. 201; no. C; p. 110051
Main Authors: Alonso-Álvarez, D., Augusto, A., Pearce, P., Llin, L. Ferre, Mellor, A., Bowden, S., Paul, D.J., Ekins-Daukes, N.
Format: Journal Article
Language:English
Published: Amsterdam Elsevier B.V 01-10-2019
Elsevier BV
Elsevier
Subjects:
Aluminum
Amorphous silicon
Ellipsometry
Emissivity
Heterojunction
Heterojunctions
Indium tin oxides
Modelling
Optimization
Photovoltaic cells
Photovoltaics
Silicon
Silicon wafers
Solar cells
Tin
Transfer matrices
Solar cells
Emissivity
Silicon
Modelling
Heterojunction
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Summary:The aim of this work is to evaluate whether silicon heterojunction solar cells, lacking highly emissive, heavily doped silicon layers, could be better candidates for hybrid photovoltaic thermal collectors than standard aluminium-diffused back contact solar cells. To this end, the near and mid infrared emissivity of full silicon heterojunction solar cells, as well as of its constituent materials – crystalline silicon wafer, indium tin oxide, n-, i- and p-type amorphous silicon – have been assessed by means of ellipsometry and FTIR. The experimental results show that the thermal emissivity of these cells is actually as high as in the more traditional structures, ~80% at 8 μm. Detailed optical modelling combining raytracing and transfer matrix formalism shows that the emissivity in these cells originates in the transparent conductive oxide layers themselves, where the doping is not high enough to result in a reflection that exceeds the increased free carrier absorption. Further modelling suggests that it is possible to obtain lower emissivity solar cells, but that a careful optimization of the transparent conductive layer needs to be done to avoid hindering the photovoltaic performance. •Hybrid photovoltaic-solar thermal systems require low thermal emissivity.•High doping combined with textures are responsible for high emissivity.•Silicon heterojunction solar cells have no highly doped silicon layers.•Experiment and modelling prove that emissivity of silicon layers is very low.•Transparent conductive oxide layers still result in overall high thermal emissivity.
Bibliography:USDOE
EEC-1041895
ISSN:0927-0248
1879-3398
DOI:10.1016/j.solmat.2019.110051