MoS<sub>2</sub>–HgTe Quantum Dot Hybrid Photodetectors beyond 2 µm

Huo, Nengjie; Gupta, Shuchi; Konstantatos, Gerasimos

doi:10.1002/adma.201606576

Cited by 277 publications

(316 citation statements)

References 37 publications

(61 reference statements)

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“…In the hybrid architectures, the TiO 2 layer between the HgTe QDs layer and the MoS 2 channel serves as an electronic receiving medium facilitating the electrons transfer to the MoS 2 and as a protective layer of the MoS 2 avoiding the effect from adsorbates such as oxygen and H 2 O in the air. In combination with the two points above, the hybrid device attained a prominent responsivity up to 10 6 A W −1 , a detectivity of 10 12 Jones, and a fast response on the order of milliseconds …”

Section: Hybrid Heterostructures Based On 2d Metal Chalcogenides For mentioning

confidence: 65%

“…The remarkable performance benefited from the strong absorption of infrared light by PbS QDs and high carrier mobility of 20 cm 2 V −1 s −1 in the MoS 2 . More recently, Huo et al demonstrated a novel hybrid phototransistor operating beyond 2 µm light (Figure d), in which HgTe QDs were integrated on a TiO 2 covered few‐layer MoS 2 . Due to the high absorption of the HgTe QDs, a mass of photoinduced carriers are generated in the HgTe QDs, and the electrons can be transferred into the MoS 2 .…”

Section: Hybrid Heterostructures Based On 2d Metal Chalcogenides For mentioning

confidence: 99%

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2D Metal Chalcogenides for IR Photodetection

Wang

Zhang

Gao

et al. 2019

Small

139

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Infrared (IR) photodetectors are finding diverse applications in imaging, information communication, military, etc. 2D metal chalcogenides (2DMCs) have attracted increasing interest in view of their unique structures and extraordinary physical properties. They have demonstrated outstanding IR detection performance including high responsivity and detectivity, high on/off ratio, fast response rate, stable room temperature operability, and good mechanical flexibility, which has opened up a new prospect in next‐generation IR photodetectors. This Review presents a comprehensive summary of recent progress in advanced IR photodetectors based on 2DMCs. The rationale of the photodetectors containing photocurrent generation mechanisms and performance parameters are briefly introduced. The device performances of 2DMCs‐based IR photodetectors are also systematically summarized, and some representative achievements are highlighted as well. Finally, conclusions and outlooks are delivered as a guideline for this thriving field.

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Section: Hybrid Heterostructures Based On 2d Metal Chalcogenides For mentioning

confidence: 65%

Section: Hybrid Heterostructures Based On 2d Metal Chalcogenides For mentioning

confidence: 99%

2D Metal Chalcogenides for IR Photodetection

Wang

Zhang

Gao

et al. 2019

Small

139

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“…The material form options for light sensitizers can either be single crystals, thin films, heterojunctions, or even discrete quantum dots. [173,174] Due to the quantum confinement effect, the bandgap of CQDs can be continuously tuned by varying the QDs size, allowing MIR absorption ability with a wavelength longer than 3 µm for HgTe QDs, providing great potential for IR sensing of this kind of material despite the material's toxicity. Meanwhile, the selection of the bottom semiconductor can focus on large bandgap organic small molecules with high mobility and a large on/off ratio to enhance both the photoresponsivity and sensing dynamic range, or 2D-like organic single crystals to obtain an extremely low dark current.…”

Section: Hybrid Phototransistormentioning

confidence: 99%

Organic Field‐Effect Transistor for Energy‐Related Applications: Low‐Power‐Consumption Devices, Near‐Infrared Phototransistors, and Organic Thermoelectric Devices

Ren

Yang

Gao

et al. 2018

Advanced Energy Materials

105

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The operating frequency of ring oscillators or radio-frequency identification tags made by OFETs have surpassed MHz. [27,28] With the growing level of integration and the operating frequency of OFETs, the power dissipation issue can no longer be ignored. Considering the material composition of most organic semiconductors, controlling the temperature rise within a reasonable range is important to avoid the unwanted degradation of organic materials and therefore maintain stable device operation. In addition, OFETs fabricated on flexi ble substrates somehow limit the use of conventional batteries. To avoid externally wiring the batteries, flexible OFET-based circuits can be expected to be self-powered by integrating them with organic solar cells, thermoelectric modules, or triboelectric nanogenerators. [29,30] All of these demands require OFETs operating with extremely low power consumption. Rapid progress has been made in this field, and research efforts have focused on reducing the operating voltage of OFETs, [31][32][33] enhancing the switching efficiency of transistors, [34][35][36][37] and demonstrating several novel device concepts for low-power applications. [38][39][40][41][42] Despite the switching function, OFETs can also be utilized in emerging energy-related applications, such as near-infrared (NIR) photodetectors and organic thermoelectric devices dueThe organic field-effect transistor (OFET) is the basic building block of integrated circuits. The charge carrier mobility and operating frequency of OFETs have continued to increase; therefore, the power dissipation of OFETs can no longer be ignored. Many research efforts have been made to develop low-power-consumption OFETs and complementary circuits. Despite the switching function, OFETs can also be utilized in emerging energy-related applications, such as near-infrared (NIR) photodetectors and organic thermoelectric devices. Organic phototransistors show considerably higher photo responsivity than other photodetector architectures due to field-effect charge modulation. The photoinduced gate modulating largely suppresses the dark current while simultaneously providing gain. These characteristics may favor NIR light detection and suggest that the organic phototransistor is a promising candidate for optoelectronic applications in the NIR regime. For organic thermoelectric applications, OFETs can work as a powerful tool for examining the charge and energy transport in the organic semiconductor, thus giving insight into organic thermoelectric studies. In this review, the authors highlight recent advances in OFET-related energy topics, including lowpower-consumption OFETs, NIR photodetectors, and organic thermoelectric devices. The remaining challenges in the field will also be discussed.

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“…In the recent years, HgTe has been widely used to explore devices with absorption above 2 μm . Pushing the nanocrystal absorption toward longer wavelength requires to update the device architecture.…”

Section: Discussionmentioning

confidence: 99%

Designing Photovoltaic Devices Using HgTe Nanocrystals for Short and Mid‐Wave Infrared Detection

Martinez

Livache

Chu

et al. 2019

Physica Status Solidi (a)

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HgTe nanocrystals offer a unique combination of broadly tunable optical absorption in the infrared from 1 to 100 μm and photoconductive properties. Herein, some of the recent developments related to their integration into photodiodes are discussed. Concepts such as the development of colloidal unipolar barrier, development of ink to achieve strongly absorbing and conductive film, and the recent proposition of intraband photodiode are also discussed.

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MoS₂–HgTe Quantum Dot Hybrid Photodetectors beyond 2 µm

Cited by 277 publications

References 37 publications

2D Metal Chalcogenides for IR Photodetection

2D Metal Chalcogenides for IR Photodetection

Organic Field‐Effect Transistor for Energy‐Related Applications: Low‐Power‐Consumption Devices, Near‐Infrared Phototransistors, and Organic Thermoelectric Devices

Designing Photovoltaic Devices Using HgTe Nanocrystals for Short and Mid‐Wave Infrared Detection

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MoS2–HgTe Quantum Dot Hybrid Photodetectors beyond 2 µm

Cited by 277 publications

References 37 publications

2D Metal Chalcogenides for IR Photodetection

2D Metal Chalcogenides for IR Photodetection

Organic Field‐Effect Transistor for Energy‐Related Applications: Low‐Power‐Consumption Devices, Near‐Infrared Phototransistors, and Organic Thermoelectric Devices

Designing Photovoltaic Devices Using HgTe Nanocrystals for Short and Mid‐Wave Infrared Detection

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MoS₂–HgTe Quantum Dot Hybrid Photodetectors beyond 2 µm