Multiheterojunction Phototransistors Based on Graphene鈥揚bSe Quantum Dot Hybrids

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• 作者：Yating Zhang ; Mingxuan Cao ; Xiaoxian Song ; Jianlong Wang ; Yongli Che ; Haitao Dai ; Xin Ding ; Guizhong Zhang ; Jianquan Yao
• 刊名：Journal of Physical Chemistry C
• 出版年：2015
• 出版时间：September 17, 2015
• 年：2015
• 卷：119
• 期：37
• 页码：21739-21743
• 全文大小：330K
• ISSN：1932-7455

文摘

Graphene-semiconductor quantum dot (QD) hybrid field effect phototransistors (FEpTs) have attracted much interest due to their ultrahigh gain and responsivity in photo detection. However, most reported results are based on single-layer heterojunction, and the multiheterojunction FEpTs are often ignored. Here, we design two typical multiheterojunction FEpTs based on graphene鈥揚bSe quantum dot (QD) hybrids, including QD at the bottom layer (QD-bottom) and graphene at the bottom layer (G-bottom) FEpTs. Through a comparative study, G-bottom FEpTs showed a multisaturation behavior due to the multigraphene layer effect, which was absent in the QD-bottom FEpTs. The mobilities for electrons and holes were 渭_E = 147 cm² V^鈥? s^鈥? and 渭_E = 137 cm² V^鈥? s^鈥? in the G-bottom FEpTs and 渭_E = 14 cm² V^鈥? s^鈥? and 渭_E = 59 cm² V^鈥? s^鈥? in the QD-bottom FEpTs. Higher responsivity (鈭?0⁶ A W^鈥?) and faster response rate were both achieved by the G-bottom FEpTs. All of the advantages in G-bottom FEpTs were attributed to the back-gate effect. Therefore, high performance is expected in those FEpTs whose heterojunctions are designed to be close to the back-gate.