Photoresponse of CVD Grown Crystalline Quantum Dot-embedded Covalent Organic Framework Thin Film

Overview

Journal RSC Adv

Publisher Royal Society of Chemistry

Specialty Chemistry

Date 2023 Feb 9

PMID 36756569

Authors

Neha Chaki Roy

Tapanendu Kundu

Affiliations

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Abstract

Covalent organic frameworks (COFs) are a new family of novel 2D materials which are highly sought after for integration into future sensors and other devices for their highly porous structures and large surface areas. However, low-temperature large-area growth of these semiconductive materials with a clean surface for direct device applications is still a challenging task. To provide an on-chip photonic device, a COF366-Quantum dot (COF366-QDs) thin-film-based device fabricated by chemical vapor deposition (CVD) is presented. The high-resolution transmission electron microscopy (HRTEM) displays the formation of the periodic, crystalline and porous framework of the COF layer with mono-dispersed QDs of average particle size of ∼2.5-3 nm. The fabricated COF366-QD layer acts as a photoactive layer in the photonic device with an Au-COFQD-Au structure where a conduction path is formed between the metal electrodes through a network of COF layer with embedded QDs. The device shows photoactive response under 514 nm visible light with a very low dark current of 4.36 × 10 A with a minimum light detection capability of 160 nW and a responsivity of ∼3.42 A W. The photonic device was highly stable for successive switching cycles with very low attenuation. To our knowledge, this is the first report of a Quantum dot embedded COF366 thin-film by chemical vapor deposition. The proposed interfacing of COF366-QD thin-films on silicon substrate using low-temperature CVD technique can be highly valuable for the development of transfer-free, clean, and low-cost preparation of industrial-scale organic electronics, optoelectronic device applications, and lab-on-chip based technologies for a wide range of future applications.

Citing Articles

Analysis of COF-300 synthesis: probing degradation processes and 3D electron diffraction structure.

Bourda L, Bhandary S, Ito S, Gob C, Van Der Voort P, Van Hecke K IUCrJ. 2024; 11(Pt 4):510-518.

PMID: 38727171 PMC: 11220877. DOI: 10.1107/S2052252524003713.

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