# Surface and bulk effects of K in highly efficient   Cu$_{1-x}$K$_x$InSe$_2$ solar cells

**Authors:** Christopher P. Muzzillo, Jian V. Li, Lorelle M. Mansfield, Kannan, Ramanathan, and Timothy J. Anderson

arXiv: 1704.01560 · 2017-04-06

## TL;DR

This study investigates how potassium (K) affects the efficiency and recombination in CuInSe2-based solar cells, revealing that K improves performance through different mechanisms at the surface and in the bulk, achieving record efficiencies.

## Contribution

It provides new insights into the distinct roles of K at the surface and in the bulk of CuInSe2 solar absorbers, optimizing growth conditions for enhanced PV performance.

## Key findings

- Optimal K distribution at x ~ 0.07 enhances efficiency to 15%.
- Surface KInSe2 layers improve efficiency and reduce interface recombination.
- Bulk K incorporation reduces recombination but can decrease performance at high concentrations.

## Abstract

To advance knowledge of K bonding in Cu(In,Ga)(Se,S)2 (CIGS) photovoltaic (PV) absorbers, recent Cu-K-In-Se phase growth studies have been extended to PV performance. First, the effect of distributing K throughout bulk Cu1-xKxInSe2 absorbers at low K/(K+Cu) compositions (0 <= x <= 0.30) was studied. Efficiency, open-circuit voltage (VOC), and fill factor (FF) were greatly enhanced for x ~ 0.07, resulting in an officially-measured 15.0%-efficient solar cell, matching to the world record CuInSe2 efficiency. The improvements were a result of reduced interface and bulk recombination, relative to CuInSe2 (x ~ 0). However, higher x compositions had reduced efficiency, short-circuit current density (JSC), and FF due to greatly increased interface recombination, relative to the x ~ 0 baseline. Next, the effect of confining K at the absorber/buffer interface at high K/(K+Cu) compositions (0.30 <= x <= 0.92) was researched. Previous work showed that these surface layer growth conditions produced CuInSe2 with a large phase fraction of KInSe2. After optimization (75 nm surface layer with x ~ 0.41), these KInSe2 surface samples exhibited increased efficiency (officially 14.9%), VOC, and FF as a result of decreased interface recombination. The KInSe2 surfaces had features similar to previous reports for KF post-deposition treatments (PDTs) used in world record CIGS solar cells-taken as indirect evidence that KInSe2 can form during these PDTs. Both the bulk and surface growth processes greatly reduced interface recombination. However, the KInSe2 surface had higher K levels near the surface, greater lifetimes, and increased inversion near the buffer interface, relative to the champion bulk CKIS absorber. These characteristics demonstrate that K may benefit PV performance by different mechanisms at the surface and in the absorber bulk.

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Source: https://tomesphere.com/paper/1704.01560