Investigation of carrier collection in multi-quantum well solar cells by luminescence spectra analysis

Multi-Quantum well solar cells (MQWSC) have been shown to present several advantages, among which are low dark currents and tunable bandgaps. They are especially suited for implementation in multi-junction cells, and are highly promising for absorbers in Hot Carrier Solar Cells (HCSC). Such applications require high concentration ratio, which arises the issue of collection efficiency. Whereas it is usually considered that collection in MQW is very close to unity at one sun, it has been shown to not be the case under high concentration at the maximum power point. We propose in this work to take advantage of the luminescence spectral variation to investigate the depth collection efficiency. In order to validate the model, a series of strain compensated InGaAs/GaAsP MQW solar cells with intentional variation of the MQW doping concentration are grown. This has the effect of switching the space charge region position and width as well as the electric field intensity. Recording the luminescence spectra at various illumination intensities and applied voltages, we show that the in-depth quasi-Fermi level splitting and thus collection properties can be probed. Other measurements (EQE, luminescence intensity variation) are shown to be consistent with these results. Regarding their use as HCSC, the luminescence of MQW solar cells has been mainly used so far for investigating the quasi-Fermi level splitting and the temperature. Our results improve our understanding by adding information on carrier transport.

[1]  Yoshiaki Nakano,et al.  A quantum-well superlattice solar cell for enhanced current output and minimized drop in open-circuit voltage under sunlight concentration , 2013 .

[2]  Levi,et al.  Hot-carrier cooling in GaAs: Quantum wells versus bulk. , 1993, Physical review. B, Condensed matter.

[3]  C. C. Button,et al.  Steady-state carrier escape from single quantum wells , 1993 .

[4]  C. C. Button,et al.  Space charge effects in carrier escape from single quantum well structures , 1999 .

[5]  William G. Oldham,et al.  The temperature variation of the electron diffusion length and the internal quantum efficiency in GaAs electroluminescent diodes , 1972 .

[6]  Yoshiaki Nakano,et al.  InGaAs/GaAsP superlattice solar cells with reduced carbon impurity grown by low-temperature metal-organic vapor phase epitaxy using triethylgallium , 2014 .

[7]  Wilhelm Warta,et al.  Diffusion lengths of silicon solar cells from luminescence images , 2007 .

[8]  Robert R. Alfano,et al.  Carrier screening effects in photoluminescence spectra of InGaAsP/InP multiple quantum well photovoltaic structures , 2001 .

[9]  C. Monier,et al.  Critical built-in electric field for an optimum carrier collection in multiquantum well p-i-n diodes , 1999 .

[10]  Antonio Martí,et al.  Absolute limiting efficiencies for photovoltaic energy conversion , 1994 .

[11]  J. P. Connolly,et al.  Strained and strain-balanced quantum well devices for high-efficiency tandem solar cells , 2001 .

[12]  L. Lombez,et al.  Thermalisation rate study of GaSb-based heterostructures by continuous wave photoluminescence and their potential as hot carrier solar cell absorbers , 2012 .

[13]  P. Würfel,et al.  The chemical potential of radiation , 1982 .