posted on 2020-03-19, 12:37authored byMenghan Zhao, Zhongying Xue, Wei Zhu, Gang Wang, Shiwei Tang, Zhiduo Liu, Qinglei Guo, Da Chen, Paul K. Chu, Guqiao Ding, Zengfeng Di
Three-dimensional
graphene (3D-Gr) with excellent light absorption properties has received
enormous interest, but in conventional processes to prepare 3D-Gr,
amorphous carbon layers are inevitably introduced as buffer layers
that may degrade the performance of graphene-based devices. Herein,
3D-Gr is prepared on germanium (Ge) using two-dimensional graphene
(2D-Gr) as the buffer layer. 2D-Gr as the buffer layer facilitates
the in situ synthesis of 3D-Gr on Ge by plasma-enhanced chemical vapor
deposition (PECVD) by promoting 2D-Gr nucleation and reducing the
barrier height. The growth mechanism is investigated and described.
The enhanced light absorption as confirmed by theoretical calculation
and 3D-Gr/2D-Gr/Ge with a Schottky junction improves the performance
of optoelectronic devices without requiring pre- and post-transfer
processes. The photodetector constructed with 3D-Gr/2D-Gr/Ge shows
an excellent responsivity of 1.7 A W–1 and detectivity
3.42 × 1014 cm Hz1/2 W–1 at a wavelength of 1550 nm. This novel hybrid structure that incorporates
3D- and 2D-Gr into Ge-based integrated circuits and photodetectors
delivers excellent performance and has large commercial potential.