Nonlocal Response in Infrared Detector with Semiconducting Carbon Nanotubes and Graphdiyne

Zheng, Zhe; Fang, Hehai; Liú, Dan; Tan, Zhenjun; Gao, Xin; Hu, Weida; Peng, Hailin; Tong, Lianming; Hu, Wenping; Zhang, Jin

doi:10.1002/advs.201700472

Cited by 29 publications

(27 citation statements)

References 28 publications

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“…GDY was reported to be able to promote the dissociation of excitons without influencing the electrical performance of the SWNT film (Figure 74). 376 The IR detector fabricated with SWNTs and GDY exhibited excellent and uniform response. Besides a fast response time below 1 ms of this IR detector being demonstrated, the optimal responsivity of 0.4 mA W −1 and detectivity of ∼5 × 10 6 cm Hz 1/2 W −1 can also be realized.…”

Section: Chemical Reviewsmentioning

confidence: 99%

Progress in Research into 2D Graphdiyne-Based Materials

et al. 2018

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Graphynes (GYs) are carbon allotropes with single-atom thickness that feature layered 2D structure assembled by carbon atoms with sp - and sp - hybridization form. Various functional theories have predicted GYs to have natural band gap with Dirac cones structure, presumably originating from inhomogeneous π-bonding between those carbon atoms with different hybridization and overlap of the carbon 2p orbitals. Among all the GYs, graphdiyne (GDY) was the first reported to be prepared practically and, hence, attracted the attention of many researchers toward this new planar, layered material, as well as other GYs. Several approaches have been reported to be able to modify the band gap of GDY, containing invoking strain, boron/nitrogen doping, nanoribbon architectures, hydrogenation, and so on. GDY has been well-prepared in many different morphologies, like nanowires, nanotube arrays, nanowalls, nanosheets, ordered stripe arrays, and 3D framwork. The fascinating structure and electronic properties of GDY make it a potential candidate carbon material with many applications. It has recently revealed the practicality of GDY as catalyst; in rechargeable batteries, solar cells, electronic devices, magnetism, detector, biomedicine, and therapy; and for gas separation as well as water purification.

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Section: Chemical Reviewsmentioning

confidence: 99%

Progress in Research into 2D Graphdiyne-Based Materials

et al. 2018

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“…Graphdiyne (GDY), a new 2D carbon‐allotrope material consisting of hybrid states of sp 2 from benzene rings and sp from acetenyl groups, has been synthesized in recent years [ 15 , 16 , 17 ] and has shown great performances in various applications. [ 18 , 19 ] The charge trapping ability of graphdiyne has also been reported in many devices, like infrared detector, [ 20 ] high‐performance UV detector, [ 21 ] and resistive random access memory devices. [ 22 ] However, 2D GDY with relatively large‐area and smooth surface is difficult to obtain due to its sophisticated growth process, which poses a restraint on its desirable van der Waals coupling with other 2D materials.…”

Section: Introductionmentioning

confidence: 99%

Direct Charge Trapping Multilevel Memory with Graphdiyne/MoS₂ Van der Waals Heterostructure

et al. 2021

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Direct charge trapping memory, a new concept memory without any dielectric, has begun to attract attention. However, such memory is still at the incipient stage, of which the charge‐trapping capability depends on localized electronic states that originated from the limited surface functional groups. To further advance such memory, a material with rich hybrid states is highly desired. Here, a van der Waals heterostructure design is proposed utilizing the 2D graphdiyne (GDY) which possesses abundant hybrid states with different chemical groups. In order to form the desirable van der Waals coupling, the plasma etching method is used to rapidly achieve the ultrathin 2D GDY with smooth surface for the first time. With the plasma‐treated 2D GDY as charge‐trapping layer, a direct charge‐trapping memory based on GDY/MoS2 is constructed. This bilayer memory is featured with large memory window (90 V) and high degree of modulation (on/off ratio around 8 × 107). Two operating mode can be achieved and data storage capability of 9 and 10 current levels can be obtained, respectively, in electronic and opto‐electronic mode. This GDY/MoS2 memory introduces a novel application of GDY as rich states charge‐trapping center and offers a new strategy of realizing high performance dielectric‐free electronics, such as optical memories and artificial synaptic.

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“…This can be attributed to the lack of efficient exciton dissociation as a result of the strong binding energy of excitons in SWCNTs, and the quenching of excitons by m‐SWCNTs which is undesirable for constructing high‐performance devices. Indeed, s‐SWCNT‐based photodetectors have shown excellent performance that can be comparable to the high‐performance commercial detectors . For instance, an s‐SWCNT‐film based IR photodetector was introduced by Liu et al This high‐performance IR detector can operate at room temperature with highly improved detection capability comparable to other room temperature IR photodetectors based on other semiconductor materials and has a broadband response (785–2100 nm), excellent stability and large‐scale fabrication compatibility.…”

Section: Transistorsmentioning

confidence: 99%

“…To conquer this obstacle, p–n junctions, heterojunctions, and asymmetric electrodes have been reported in order to enhance exciton dissociation . For instance, the performance of s‐SWCNT‐based photodetectors was greatly enhanced by utilizing fullerene (C 60 ), graphene, and γ‐graphdiyne . Here, the impact of m‐ and s‐SWCNTs on the photodetection process was also investigated .…”

Section: Transistorsmentioning

confidence: 99%

Recent Advances in Applications of Sorted Single‐Walled Carbon Nanotubes

Bati

Batmunkh

et al. 2019

Adv Funct Materials

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Single-walled carbon nanotubes (SWCNTs) exhibit outstanding properties that make them appealing in a wide range of applications. However, their properties are variable depending on the tube helicity (chirality), which has been a challenge for a long time and needs to be effectively controlled. In recent years, tremendous efforts have been made to control the electrical type/chirality of nanotubes through both direct controlled synthesis and postsynthesis separation methods. Driven by these breakthroughs, the applications of separated families of SWCNTs in various fields have emerged as a new topic of research. In this Review, an overview of recent advances in the use of highly purified and well-separated SWCNTs in a comprehensive range of applications is presented including photovoltaics, transistors, batteries, sensors, light emitters, biological/medical fields, and others. Finally, important future directions for the utilization of separated SWCNTs in these fields are provided.

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Nonlocal Response in Infrared Detector with Semiconducting Carbon Nanotubes and Graphdiyne

Cited by 29 publications

References 28 publications

Progress in Research into 2D Graphdiyne-Based Materials

Progress in Research into 2D Graphdiyne-Based Materials

Direct Charge Trapping Multilevel Memory with Graphdiyne/MoS₂ Van der Waals Heterostructure

Recent Advances in Applications of Sorted Single‐Walled Carbon Nanotubes

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Nonlocal Response in Infrared Detector with Semiconducting Carbon Nanotubes and Graphdiyne

Cited by 29 publications

References 28 publications

Progress in Research into 2D Graphdiyne-Based Materials

Progress in Research into 2D Graphdiyne-Based Materials

Direct Charge Trapping Multilevel Memory with Graphdiyne/MoS2 Van der Waals Heterostructure

Recent Advances in Applications of Sorted Single‐Walled Carbon Nanotubes

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Direct Charge Trapping Multilevel Memory with Graphdiyne/MoS₂ Van der Waals Heterostructure