Optical absorption of graded buffer layers and short circuit current improvement in SiGe solar cells grown on silicon substrates

Optical absorption of graded buffer layers and short circuit current improvement in SiGe solar cells grown on silicon substrates

A compositionally graded silicon germanium (Si1−xGex) buffer layer is a leverage technology that grows III–V materials on silicon (Si) substrates with low threading dislocation density. This study determined average optical absorption coefficients of Si1−xGex graded buffer layers at wavelengths beyo...

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Bibliographic Details
Published in:Solar energy materials and solar cells Vol. 157; pp. 973 - 980
Main Authors: Li, Dun, Zhao, Xin, Wang, Li, Conrad, Brianna, Soeriyadi, Anastasia H., Diaz, Martin, Gerger, Andrew, Lochtefeld, Anthony, Barnett, Allen, Perez-Wurfl, Ivan
Format: Journal Article
Language:English
Published: Elsevier B.V 01-12-2016
Subjects:
Absorption coefficients
Graded buffer layer
III–V on Si
Silicon germanium
Tandem solar cell
Tandem solar cell
III–V on Si
Absorption coefficients
Graded buffer layer
Silicon germanium
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Summary:A compositionally graded silicon germanium (Si1−xGex) buffer layer is a leverage technology that grows III–V materials on silicon (Si) substrates with low threading dislocation density. This study determined average optical absorption coefficients of Si1−xGex graded buffer layers at wavelengths beyond the band gap of Si by measuring the transmittances of Si1−xGex on Si wafers. The results show that assuming linear changes of absorption coefficients of Si1−xGex with the change of germanium (Ge) composition will significantly overestimates the absorption in the Si1−xGex graded buffer layers. Using determined average absorption coefficients of graded buffer layers, an accurate optical model was developed for a fabricated planar Si0.15Ge0.85 on Si solar cell. This model shows that significant amounts of light at the band edge of Si are absorbed by the Si substrate. However, the majority of the light absorbed by the Si substrate cannot contribute to the short-circuit current of the solar cell, as the generated electron-hole carriers are too far away from the p-n junction and thus have a very low probability of being collected by the p-n junction. By thinning the Si substrate from 675µm to 200µm, a 0.5mA/cm2 short-circuit current density (JSC) improvement under AM1.5G spectrum was observed on the Si0.15Ge0.85 solar cell. Further thinning the Si substrate to 50µm should lead to a total JSC gain of 1.6mA/cm2. This study provides a practical path for achieving a highly efficient two-terminal current matched GaAsP/SiGe tandem solar cell on Si substrate. •Average absorption coefficients of Si1−xGex graded buffer layers were determined.•Si substrates absorb significant amounts of light in SiGe on Si solar cells.•JSC improvement has been observed by thinning the Si substrate.•Optical absorption in the SiGe graded buffer layers would contribute to the JSC.
ISSN:0927-0248
1879-3398
DOI:10.1016/j.solmat.2016.08.019