posted on 2021-08-16, 14:11authored byO Oklobia, G Kartopu, S Jones, P Siderfin, B Grew, HKH Lee, WC Tsoi, Ali AbbasAli Abbas, Michael WallsMichael Walls, DL McGott, MO Reese, SJC Irvine
Recent developments in CdTe solar cell technology have included the incorporation of
ternary alloy Cd(Se,Te) in the devices. CdTe absorber band gap grading due to Se
alloying contributes to current density enhancement and can result in device
performance improvement. Here we report Cd(Se,Te) polycrystalline thin films grown
by a chamberless inline atmospheric pressure metal organic chemical vapour
deposition technique, with subsequent incorporation in CdTe solar cells. The
compositional dependence of the crystal structure and optical properties of Cd(Se,Te)
are examined. Selenium graded Cd(Se,Te)/CdTe absorber structure in devices are
demonstrated using either a single CdSe layer or CdSe/Cd(Se,Te) bilayer (with or
without As doping in the Cd(Se,Te) layer). Cross-sectional TEM/EDS,
photoluminescence spectra and secondary ion mass spectroscopy analysis confirmed
the formation of a graded Se profile toward the back contact with a diffusion length of
∼1.5 μm and revealed back-diffusion of Group V (As) dopants from the CdTe layer into
Cd(Se,Te) grains. Due to the strong Se/Te interdiffusion, CdSe in the Se bilayer
configuration was unable to form an n-type emitter layer in processed devices. In situ
As doping of the Cd(Se,Te) layer benefited the device junction quality with current
density reaching 28.3 mA/cm 2 . The results provide useful insights for the
optimisation of Cd(Se,Te)/CdTe solar cells.
Funding
European Regional Development Fund (ERDF) and the Welsh European Funding Office (WEFO) for funding the 2nd Solar Photovoltaic Academic Research Consortium (SPARC II)
SPECIFIC IKC Phase 2
Engineering and Physical Sciences Research Council
This paper was accepted for publication in the journal Solar Energy Materials and Solar Cells and the definitive published version is available at https://doi.org/10.1016/j.solmat.2021.111325