Issue 12, 2016

High-efficiency, stable and non-chemically doped graphene–Si solar cells through interface engineering and PMMA antireflection

Abstract

In graphene–Si (Gr–Si) solar cells, chemical doping could remarkably enhance the performance of the cells, but weakens their stability, which limits their further application. However, in terms of the efficiency of pristine cells, the interfacial defect states and the increased thickness of the oxide layer in air also make high-efficiency and stable cells more difficult to achieve. Here we directly grew carbon nanowalls (CNWs) as a passivation layer onto the Si surface, which could obviously increase the efficiency. On the other hand, a poly(methyl-methacrylate) (PMMA) film was retained after transferring graphene, which could not only keep the graphene intact, but could also serve as an efficient antireflection layer for greater light absorption of the Si. A maximum PCE of 8.9% was achieved for a PMMA-bilayer Gr-CNWs-Si solar cell. Our cell’s efficiency showed a slight degradation after being stored in air for 4 months. This result is far superior to other previously reported stability data for chemically doped Gr–Si solar cells. The PMMA-Gr-CNWs-Si solar cell, with high efficiency and stability, possesses important potential for practical photovoltaic applications.

Graphical abstract: High-efficiency, stable and non-chemically doped graphene–Si solar cells through interface engineering and PMMA antireflection

Supplementary files

Article information

Article type
Communication
Submitted
26 Oct 2015
Accepted
15 Jan 2016
First published
19 Jan 2016

RSC Adv., 2016,6, 10175-10179

High-efficiency, stable and non-chemically doped graphene–Si solar cells through interface engineering and PMMA antireflection

T. Jiao, D. Wei, X. Song, T. Sun, J. Yang, L. Yu, Y. Feng, W. Sun, W. Wei, H. Shi, C. Hu and C. Du, RSC Adv., 2016, 6, 10175 DOI: 10.1039/C5RA22418G

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