Gaoqi Cao scite author profile

Two-dimensional heterojunctions exhibit many unique features in nanoelectronic and optoelectronic devices. However, heterojunction engineering requires a complicated alignment process and some defects are inevitably introduced during material preparation. In this work, a laser scanning technique is used to construct a lateral WSe2 p–n junction. The laser-scanned region shows p-type behavior, and the adjacent region is electrically n-doped with a proper gate voltage. The laser-oxidized product WO x is found to be responsible for this p-type doping. After laser scanning, WSe2 displays a change from ambipolar to unipolar p-type property. A significant photocurrent emerges at the p–n junction. Therefore, a self-powered WSe2 photodetector can be fabricated based on this junction, which presents a large photoswitching ratio of 106, a high photoresponsivity of 800 mA W–1, and a short photoresponse time with long-term stability and reproducibility. Therefore, this selective laser-doping method is prospective in future electronic applications.

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Multicolor Broadband and Fast Photodetector Based on InGaAs–Insulator–Graphene Hybrid Heterostructure

Cao

Wang

Peng

et al. 2020

Adv Elect Materials

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Broadband light detection is crucial for a variety of optoelectronic applications in modern society. As an important‐near infrared (NIR) photodetector, InGaAs PIN photodiodes demonstrate high detection performance. However, they have a limited response range because of optical absorption by the window layer or substrate. To exploit the broadband absorption capability of narrow‐bandgap InGaAs, a phototransistor based on a hybrid InGaAs‐SiO2‐graphene heterostructure is presented. In this system, graphene serves as a transparent conducting channel to sense optical absorption in the InGaAs. In contrast to InGaAs PIN photodiodes, the hybrid InGaAs phototransistor demonstrates multicolor photodetection over a broadband wavelength range from the ultraviolet to NIR. Furthermore, it manifests a high photoresponsivity of above 103 A W−1 under weak light irradiation, a large external quantum efficiency, and a fast response speed of 200 kHz. The results pave the way for the development of high‐performance broadband photodetectors based on mixed‐dimensional heterostructures.

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Broadband high quantum efficiency InGaAs/InP focal plane arrays via high precision plasma thinning

Shao

et al. 2019

Opt. Lett.

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High performance In0.83Ga0.17As SWIR photodiode passivated by Al2O3/SiNx stacks with low-stress SiNx films

Wan

Cao

Shao

et al. 2019

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To develop extended InGaAs photodiode focal plane arrays with large scale and small pixels, a surface passivation film with low stress is necessary. To study the surface bowing of SiNx passivation film deposited with different conditions by inductively coupled plasma chemical vapor deposition, 2-in. InP samples were first utilized to obtain statistical results. As can be seen from the result, the bowing introduced by the passivation film is reduced to less than 10 μm when applying optimized film deposition conditions, which is a significant optimization. In the further investigation of the passivation effect on the InGaAs photodiode, Al2O3/SiNx stacks were proposed as the passivation layer, and Al2O3 was deposited by atomic layer deposition (ALD). Results demonstrate that the photodiodes passivated by the Al2O3/SiNx stacks have lower dark current density, especially at lower temperatures. At 180 K, the contribution of perimeter dark current is reduced by more than one order of magnitude. Theoretical analysis shows that the composite passivation film effectively suppresses tunneling current at 180 K.

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Interface property of silicon nitride films grown by inductively coupled plasma chemical vapor deposition and plasma enhanced chemical vapor deposition on In0.82Al0.18As

Shi

Tang

Shao

et al. 2015

Infrared Physics & Technology

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Gaoqi Cao

High-Performance WSe₂ Photodetector Based on a Laser-Induced p–n Junction

Multicolor Broadband and Fast Photodetector Based on InGaAs–Insulator–Graphene Hybrid Heterostructure

Broadband high quantum efficiency InGaAs/InP focal plane arrays via high precision plasma thinning

High performance In0.83Ga0.17As SWIR photodiode passivated by Al2O3/SiNx stacks with low-stress SiNx films

Interface property of silicon nitride films grown by inductively coupled plasma chemical vapor deposition and plasma enhanced chemical vapor deposition on In0.82Al0.18As

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Gaoqi Cao

High-Performance WSe2 Photodetector Based on a Laser-Induced p–n Junction

Multicolor Broadband and Fast Photodetector Based on InGaAs–Insulator–Graphene Hybrid Heterostructure

Broadband high quantum efficiency InGaAs/InP focal plane arrays via high precision plasma thinning

High performance In0.83Ga0.17As SWIR photodiode passivated by Al2O3/SiNx stacks with low-stress SiNx films

Interface property of silicon nitride films grown by inductively coupled plasma chemical vapor deposition and plasma enhanced chemical vapor deposition on In0.82Al0.18As

Contact Info

Product

Resources

About

High-Performance WSe₂ Photodetector Based on a Laser-Induced p–n Junction