Your search keyword '"Yan, Yanfei"' showing total 2 results

1. High Efficient Solar Cell Based on Heterostructure Constructed by Graphene and GaAs Quantum Wells.

Author

Yu, Xutao, Dai, Yue, Lu, Yanghua, Liu, Chang, Yan, Yanfei, Shen, Runjiang, Yang, Zunshan, Feng, Lixuan, Sun, Lijie, Liu, Yong, and Lin, Shisheng

Subjects

SOLAR cells, GRAPHENE, QUANTUM wells, AUDITING standards, INDIUM gallium arsenide, OPEN-circuit voltage, GALLIUM arsenide

Abstract

Despite the fascinating optoelectronic properties of graphene, the power conversion efficiency (PCE) of graphene based solar cells remains to be lifted up. Herein, it is experimentally shown that the graphene/quantum wells/GaAs heterostructure solar cell can reach a PCE of 20.2% and an open‐circuit voltage (Voc) as high as 1.16 V at 90 K. The high efficiency is a result of carrier multiplication (CM) effect of graphene in the graphene/GaAs heterostructure. Especially, the external quantum efficiency (EQE) in the ultraviolet wavelength can be improved up to 72.2% based on the heterostructure constructed by graphene/In0.15Ga0.85As/GaAs0.75P0.25 quantum wells/GaAs. The EQE increases as the light wavelength decreases, which indicates more carriers can be effectively excited by the higher energy photons through CM effect. Owing to these physical characters, the graphene/GaAs heterostructure solar cell will provide a possible way to exceed Shockley–Queisser (S–Q) limit. [ABSTRACT FROM AUTHOR]

Published

2023

2. Hot Carrier Transport and Carrier Multiplication Induced High Performance Vertical Graphene/Silicon Dynamic Diode Generator.

Author

Lu, Yanghua, Shen, Runjiang, Yu, Xutao, Yuan, Deyi, Zheng, Haonan, Yan, Yanfei, Liu, Chang, Yang, Zunshan, Feng, Lixuan, Li, Linjun, and Lin, Shisheng

Subjects

SILICON diodes, HOT carriers, GRAPHENE, ENERGY harvesting, SEMICONDUCTOR diodes, MECHANICAL energy

Abstract

Dynamic semiconductor diode generators (DDGs) offer a potential portable and miniaturized energy source, with the advantages of high current density, low internal impedance, and independence of the rectification circuit. However, the output voltage of DDGs is generally as low as 0.1–1 V, owing to energy loss during carrier transport and inefficient carrier collection, which requires further optimization and a deeper understanding of semiconductor physical properties. Therefore, this study proposes a vertical graphene/silicon DDG to regulate the performance by realizing hot carrier transport and collection. With instant contact and separation of the graphene and silicon, hot carriers are generated by the rebounding process of built‐in electric fields in dynamic graphene/silicon diodes, which can be collected within the ultralong hot electron lifetime of graphene. In particular, monolayer graphene/silicon DDG outputs a high voltage of 6.1 V as result of ultrafast carrier transport between the monolayer graphene and silicon. Furthermore, a high current of 235.6 nA is generated due to the carrier multiplication in graphene. A voltage of 17.5 V is achieved under series connection, indicating the potential to supply electronic systems through integration design. The graphene/silicon DDG has applications as an in situ energy source for harvesting mechanical energy from the environment. [ABSTRACT FROM AUTHOR]

Published

2022