Organic Source‐Gated Phototransistors with &gt; 10<sup>4</sup> Photo‐To‐Dark Current Ratio in the Visible Range at Zero Gate‐Source Bias

Bestelink, Eva; Zschieschang, Ute; Askew, Leslie; Klauk, Hagen; Sporea, Radu A.

doi:10.1002/adom.202301931

Advanced Optical Materials

2023

DOI: 10.1002/adom.202301931

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Organic Source‐Gated Phototransistors with > 10⁴ Photo‐To‐Dark Current Ratio in the Visible Range at Zero Gate‐Source Bias

Eva Bestelink,

Ute Zschieschang,

Leslie Askew

et al.

Abstract: With growing interest in organic phototransistors, as not only sensors but also neuromorphic computing elements, the vast majority of research investigates structures comprising Ohmic source/drain contacts. Here, it is shown how source‐gated transistors (SGTs), in which a source contact barrier dominates electrical characteristics, can be implemented as phototransistors. Organic photo‐SGTs (OPSGTs) based on vacuum‐processed small‐molecule dinaphtho[2,3‐b:2′,3′‐f]thieno[3,2‐]thiophene (DNTT) demonstrate low sat… Show more

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2024

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Ultraviolet Photodetector Fabrication with Low‐Power Dissipation Based on Organic Suboptimal Source‐Gated Transistor Architecture and MoO₃‐Doped Pentacene

Jung,

Kim,

Baeg

et al. 2024

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Organic field‐effect transistor (OFET)‐based photodetectors have been extensively studied owing to their potential applications in various fields, such as imaging, communication, and environmental monitoring. However, the traditional OFET structure brings about high power consumption. Furthermore, their low electrical performance and light sensitivity must be improved to detect harmful UV rays that accelerate skin aging and cause vision degradation. One strategy to fabricate high‐performance phototransistors involves the introduction of molybdenum trioxide (MoO3), which serves as a dopant for pentacene, aiming to enhance electrical performance by increasing mobility and decreasing threshold voltage. In addition, the photoreactivity of MoO3 in the UV spectrum is utilized to achieve enhanced light responsivity. In this work, a suboptimal source‐gated transistor (sSGT) is introduced instead of a conventional OFET to exploit the work function difference between two electrodes and the active layer to achieve low‐power consumption. The power of the sSGT is 1000 times lower than that of the OFET, demonstrating the low‐power consumption. The findings indicate the potential fabrication method of high‐performance UV phototransistors with low‐power consumption induced by incorporating the MoO3 and sSGT structure.

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Ultraviolet Photodetector Fabrication with Low‐Power Dissipation Based on Organic Suboptimal Source‐Gated Transistor Architecture and MoO₃‐Doped Pentacene

Jung,

Kim,

Baeg

et al. 2024

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Toward low-power-consumption source-gated phototransistor

Wang,

Liu,

Zhang

et al. 2024

Applied Physics Letters

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The power consumption is challenging the next-generation electronic and optoelectronic devices. In this Letter, the n-type source-gated transistor (SGT) enabled by CdS nanobelt is investigated in detail, demonstrating the expected low power consumption, along with impressive photodetection performance. The SGT is realized by deliberately introducing the Schottky barrier at the source of the staggered-electrode transistor, exhibiting a small saturated voltage (VSAT) of 0.84 ± 0.21 V and a remarkably low power consumption of 7.56 ± 4.01 nW. Under illumination, the as-constructed SGT also shows a low power consumption of 7.58 nW, which is much lower than that of the most reported phototransistors operating in the saturated region. Moreover, the source-gated phototransistor also shows a high responsivity of 2.54 × 103 A W−1 and a high detectivity of 6.72 × 1012 Jones. All results imply that the as-constructed low-power-consumption source-gated phototransistor promises next-generation high-performance electronic and optoelectronic devices.

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Organic Source‐Gated Phototransistors with > 10⁴ Photo‐To‐Dark Current Ratio in the Visible Range at Zero Gate‐Source Bias

Cited by 2 publications

References 41 publications

Ultraviolet Photodetector Fabrication with Low‐Power Dissipation Based on Organic Suboptimal Source‐Gated Transistor Architecture and MoO₃‐Doped Pentacene

Ultraviolet Photodetector Fabrication with Low‐Power Dissipation Based on Organic Suboptimal Source‐Gated Transistor Architecture and MoO₃‐Doped Pentacene

Toward low-power-consumption source-gated phototransistor

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Organic Source‐Gated Phototransistors with > 104 Photo‐To‐Dark Current Ratio in the Visible Range at Zero Gate‐Source Bias

Cited by 2 publications

References 41 publications

Ultraviolet Photodetector Fabrication with Low‐Power Dissipation Based on Organic Suboptimal Source‐Gated Transistor Architecture and MoO3‐Doped Pentacene

Ultraviolet Photodetector Fabrication with Low‐Power Dissipation Based on Organic Suboptimal Source‐Gated Transistor Architecture and MoO3‐Doped Pentacene

Toward low-power-consumption source-gated phototransistor

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Product

Resources

About

Organic Source‐Gated Phototransistors with > 10⁴ Photo‐To‐Dark Current Ratio in the Visible Range at Zero Gate‐Source Bias

Ultraviolet Photodetector Fabrication with Low‐Power Dissipation Based on Organic Suboptimal Source‐Gated Transistor Architecture and MoO₃‐Doped Pentacene

Ultraviolet Photodetector Fabrication with Low‐Power Dissipation Based on Organic Suboptimal Source‐Gated Transistor Architecture and MoO₃‐Doped Pentacene