# Device physics of van der Waals heterojunction solar cells

**Authors:** Marco M. Furchi, Florian H\"oller, Lukas Dobusch, Dmitry K., Polyushkin, Simone Schuler, Thomas Mueller

arXiv: 1903.03002 · 2019-03-08

## TL;DR

This paper develops a comprehensive device model for van der Waals heterojunction solar cells, revealing charge transfer efficiency, carrier accumulation, and recombination effects crucial for optimizing ultrathin photovoltaic devices.

## Contribution

It provides the first detailed device physics model that accurately reproduces experimental current-voltage behavior of atomically thin heterojunction solar cells.

## Key findings

- Efficient spatial charge transfer across the junction.
- Significant carrier accumulation due to poor transport.
- Recombination losses impact device efficiency.

## Abstract

Heterostructures based on atomically thin semiconductors are considered a promising emerging technology for the realization of ultrathin and ultralight photovoltaic solar cells on flexible substrates. Much progress has been made in recent years on a technological level, but a clear picture of the physical processes that govern the photovoltaic response remains elusive. Here, we present a device model that is able to fully reproduce the current-voltage characteristics of type-II van der Waals heterojunctions under optical illumination, including some peculiar behaviors such as exceedingly high ideality factors or bias-dependent photocurrents. While we find the spatial charge transfer across the junction to be very efficient, we also find a considerable accumulation of photogenerated carriers in the active device region due to poor electrical transport properties, giving rise to significant carrier recombination losses. Our results are important to optimize future device architectures and increase power conversion efficiencies of atomically thin solar cells.

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Source: https://tomesphere.com/paper/1903.03002