Role of Interfacial Oxide in High-efficiency Graphene-silicon Schottky Barrier Solar Cells

Overview

Journal Nano Lett

Publisher American Chemical Society

Specialty Biotechnology

Date 2015 Feb 17

PMID 25685934

Citations 23

Authors

Yi Song

Xinming Li

Charles Mackin

Xu Zhang

Wenjing Fang

Tomas Palacios

Hongwei Zhu

Jing Kong

Affiliations

Soon will be listed here.

Abstract

The advent of chemical vapor deposition (CVD) grown graphene has allowed researchers to investigate large area graphene/n-silicon Schottky barrier solar cells. Using chemically doped graphene, efficiencies of nearly 10% can be achieved for devices without antireflective coatings. However, many devices reported in past literature often exhibit a distinctive s-shaped kink in the measured I/V curves under illumination resulting in poor fill factor. This behavior is especially prevalent for devices with pristine (not chemically doped) graphene but can be seen in some cases for doped graphene as well. In this work, we show that the native oxide on the silicon presents a transport barrier for photogenerated holes and causes recombination current, which is responsible for causing the kink. We experimentally verify our hypothesis and propose a simple semiconductor physics model that qualitatively captures the effect. Furthermore, we offer an additional optimization to graphene/n-silicon devices: by choosing the optimal oxide thickness, we can increase the efficiency of our devices to 12.4% after chemical doping and to a new record of 15.6% after applying an antireflective coating.

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