Storage and transfer of optical excitation energy in GaInP epilayer: Photoluminescence signatures

doi:10.1016/j.jmst.2019.03.010

Abstract

Abstract:

GaInP alloy could be the most trusted key material for fabricating super-high-efficiency single- and multi-junction solar cells, especially for space applications. The storage and transfer of optical excitation energy in this key alloy is thus a key subject of the energy conversion from optical to electrical. In this article we present a study of the subject through investigating photoluminescence (PL) degradation in the GaInP epilayer at 4 K under the continuous optical excitations of ultraviolet (UV) 325 nm, visible 488.0 and 514.5 nm lasers. It is found that the decline of PL intensity with the irradiation time may be represented by I(t)/I₀=(1+tτ^-1)^-1+C, where I₀ is the luminescence intensity at the beginning of irradiation, τ a time constant, and C a background. Moreover, the PL degradation degree reduces with increasing the excitation wavelength. In addition, some red shift of the PL peak is observed accompanying with the intensity decline under the UV laser excitation. These PL signatures indicate that the localized carriers within the local atomic ordering domains play a major role in the storage and transfer of the excitation energy via photon recycling processes.

Key words: GaInP alloy, Photoluminescence, Energy transfer, Photon recycling

Shijie Xu, Ying Huang, Zhicheng Su, Rongxin Wang, Jianrong Dong, Deliang Zhu. Storage and transfer of optical excitation energy in GaInP epilayer: Photoluminescence signatures[J]. J. Mater. Sci. Technol., 2019, 35(7): 1364-1367.

Figures/Tables 4

Fig. 1. Photoluminescence spectra of the GaInP epilayer at 4 K under the irradiation of a 325 nm He-Cd laser line for different irradiation times. Note that the PL intensity is plotted in a semi logorithmic scale.

Fig. 2. Relative PL peak intensities (solid circles) versus irradiation time. Solid line represents a fitting curve with the empirical formula described in text.

Fig. 3. PL peak positions (solid squares) versus irradiation time. Solid line is a theoretical curve by LSE model [35].

Fig. 4. Relative PL intensities (solid symbols) versus irradiation time for the sample at 4 K under the continuous irradiation of 325 nm, 488 nm and 514.5 nm laser lines with the identical power. Solid lines are the fitting curves with Eq. (1).

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