High-Gain 200 ns Photodetectors from Self-Aligned CdS-CdSe Core-Shell Nanowalls

Jinyou Xu, Katya Rechav, Ronit Popovitz-Biro, Iftach Nevo, Yishay Feldman, Ernesto Joselevich*

*Corresponding author for this work

Research output: Contribution to journalArticlepeer-review

61 Citations (Scopus)
113 Downloads (Pure)

Abstract

1D core-shell heterojunction nanostructures have great potential for high-performance, compact optoelectronic devices owing to their high interface area to volume ratio, yet their bottom-up assembly toward scalable fabrication remains a challenge. Here the site-controlled growth of aligned CdS-CdSe core-shell nanowalls is reported by a combination of surface-guided vaporliquid-solid horizontal growth and selective-area vapor-solid epitaxial growth, and their integration into photodetectors at wafer-scale without postgrowth transfer, alignment, or selective shell-etching steps. The photocurrent response of these nanowalls is reduced to 200 ns with a gain of up to 3.8 x 10(3) and a photoresponsivity of 1.2 x 10(3) A W-1, the fastest response at such a high gain ever reported for photodetectors based on compound semiconductor nanostructures. The simultaneous achievement of sub-microsecond response and high-gain photocurrent is attributed to the virtues of both the epitaxial CdS-CdSe heterojunction and the enhanced charge-separation efficiency of the core-shell nanowall geometry. Surface-guided nanostructures are promising templates for wafer-scale fabrication of self-aligned core-shell nanostructures toward scalable fabrication of high-performance compact photodetectors from the bottom-up.
Original languageEnglish
Article number1800413
Number of pages9
JournalAdvanced Materials
Volume30
Issue number20
DOIs
Publication statusPublished - 17 May 2018

Funding

The authors thank Dr. Iddo Pinkas for the construction of AOM laser. This research was supported by European Research Council (ERC) Advanced Grant No. 338849, the Israel Science Foundation, Minerva Stiftung, Kimmel Center for Nanoscale Science, Moskowitz Center for Nano and Bio‐Nano Imaging, and the Perlman Family Foundation. E.J. is an incumbent of the Drake Family Professorial Chair in Nanotechnology.

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