Abstract
This contribution evaluates a sequential post‐deposition treatment of Cu(In,Ga)Se2 (CIGS) films, consisting of 1) a post‐sulfurization in elemental S‐atmosphere and 2) a subsequent treatment by heavy alkali fluorides (Alk‐PDT). First, the effect of the sulfurization step on the corresponding solar cell performance is investigated and optimum process parameters, leading to an efficiency improvement, are identified. Losses in carrier collection observed after S‐incorporation are attributed to an increased grain boundary (GB) recombination. It is found that the corresponding reduction in short‐circuit current density can be mitigated by a RbF‐ or KF‐PDT, supposedly by depleting GBs in Cu. However, in strong contrast to non‐sulfurized CIGS, the Alk‐PDT results in a lower open‐circuit voltage and distortions in the current–voltage (I–V) characteristics for sulfurized absorbers. Possible explanations are the absence of a wide‐gap surface phase and/or air exposure between the post‐treatment steps. It is further proposed that a back contact barrier may be responsible for the distortions in I–V.
Highlights
Introduction theS-treatment, a post-annealing of co-evaporated CIGS in either H2S[3,12,13,14] or elemental sulfur[15,16,17,18,19] was frequently studied
The spatial incorporation of heavy alkalis in sulfurized CIGS is investigated by glow discharge-optical emission spectroscopy (GDOES) and energy-dispersive X-ray spectroscopy in scanning transmission electron microscopy (STEM-EDS)
It is shown that sulfurization can improve the efficiency of low-gap CIGS solar cells by increasing VOC and fill factor (FF)
Summary
This section is separated into three paragraphs. The impact of the sulfurization parameters on the solar cell performance is presented and discussed. The effect of a subsequent KF- or RbF-PDT step is studied. The spatial incorporation of heavy alkalis in sulfurized CIGS is investigated by glow discharge-optical emission spectroscopy (GDOES) and energy-dispersive X-ray spectroscopy in scanning transmission electron microscopy (STEM-EDS). For the sake of clarity, only the current–voltage (I–V ) and external quantum efficiency (EQE) results of the best solar cell (highest efficiency) of each sample are presented. The trends for average values are identical
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