High Mobility 2D Palladium Diselenide Field‐Effect Transistors with Tunable Ambipolar Characteristics

Chow, Wai Leong; Yu, Peng; Liu, Fucai; Hong, Jinhua; Wang, Xingli; Zeng, Qingsheng; Hsu, Chuang‐Han; Zhu, Chao; Zhou, Jiadong; Wang, Xiaowei; Xia, Juan; Yan, Jiaxu; Yu, Changlin; Wu, Di; Yu, Ting; Shen, Zexiang; Lin, Hsin; Jin, Chuanhong; Tay, Beng Kang; Liu, Zheng

doi:10.1002/adma.201602969

Cited by 273 publications

(337 citation statements)

References 46 publications

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“…By virtue of the thickness variable feature, Raman measurements were also performed on the transferred PdSe 2 flakes on SiO 2 /Si to establish a one‐to‐one correspondence between thickness and Raman modes. As displayed in Figure e, three notable peaks (at ≈143.2, ≈221.8, and ≈256.1 cm −1 ) are identified as the fingerprints of bulk PdSe 2 , the same as those of the mechanically exfoliated samples . Notably, with the thickness reducing to 2L, the three vibrational modes are shifted to higher frequencies (A g 1 : ≈152.5 cm −1 ; B 1g 2 : ≈229.6 cm −1 ; A g 3 : ≈264.9 cm −1 ), showing remarkable shifts by ≈9.3, ≈7.8, and ≈8.8 cm −1 , respectively.…”

Section: Resultsmentioning

confidence: 88%

“…Raman spectroscopy was further utilized to determine the formation and air stability of PdSe 2 on Au foils (Figure f). For the freshly grown PdSe 2 sample, the Raman peaks at ≈149.5 and ≈228.1 cm −1 are attributed to A g 1 and B 1g 2 vibrational modes, relating to the movements of Se atoms, while the peak at ≈263.1 cm −1 is assigned to the A g 3 vibrational mode, due to the relative movements between Se and Pd atoms . In contrast to bulk PdSe 2 , a new peak appears at ≈124.2 cm −1 , which is explained to arise from the variation of space group from bulk to few‐layer (from Pbca to Pca2 1 ) .…”

Section: Resultsmentioning

confidence: 99%

“…Until now, most reported monolayer or few‐layer PdSe 2 samples have been achieved by mechanical exfoliation, molecular beam epitaxy (MBE), and selenization of predeposited Pd layers . Low productivity, high cost, small domain size, and uncontrolled layer thickness were usually resulted, strongly hindering the practical applications of PdSe 2 in related fields.…”

Section: Introductionmentioning

confidence: 99%

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Anisotropic Growth and Scanning Tunneling Microscopy Identification of Ultrathin Even‐Layered PdSe₂ Ribbons

Jiang

Xie

et al. 2019

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Palladium diselenide (PdSe2) is an emerging 2D layered material with anisotropic optical/electrical properties, extra‐high carrier mobility, excellent air stability, etc. So far, ultrathin PdSe2 is mainly achieved via mechanical exfoliation from its bulk counterpart, and the direct synthesis is still challenging. Herein, the synthesis of ultrathin 2D PdSe2 on conductive Au foil substrates via a facile chemical vapor deposition route is reported. Intriguingly, an anisotropic growth behavior is detected from the evolution of ribboned flakes with large length/width ratios, which is well explained from the orthorhombic symmetry of PdSe2. A unique even‐layered growth mode from 2 to 20 layers is also confirmed by the perfect combination of onsite scanning tunneling microscopy characterizations, through deliberately scratching the flake edge to expose both even and odd layers. This even‐layered, ribboned 2D material is expected to serve as a perfect platform for exploring unique physical properties, and for developing high‐performance electronic and optoelectronic devices.

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Section: Resultsmentioning

confidence: 88%

Section: Resultsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Anisotropic Growth and Scanning Tunneling Microscopy Identification of Ultrathin Even‐Layered PdSe₂ Ribbons

Jiang

Xie

et al. 2019

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“…To evaluate the Schottky barrier height between metal and WSe 2 , I DS could be defined by 2D thermionic emission (Eq. (5)) due to its sufficiently thin channel 41 .…”

Section: Resultsmentioning

confidence: 99%

“…Figure 3e shows the effective Schottky barrier as a function of the gate voltage of 1L, 7L, and 12L WSe 2 devices. A peak between −10 and 0 V in the 7L WSe 2 device is attributed to the opposite polarities of Schottky contact, which could be tuned based upon the gate voltage 41 . As seen, the effective Schottky barrier for the hole carrier is strongly dependent on the gate voltage compared to that for the electron carrier.…”

Section: Resultsmentioning

confidence: 99%

The ambipolar transport behavior of WSe2 transistors and its analogue circuits

et al. 2018

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Tungsten diselenide (WSe 2 ) has many excellent properties and provides superb potential in applications of valleybased electronics, spin-electronics, and optoelectronics. To facilitate the digital and analog application of WSe 2 in CMOS, it is essential to understand the underlying ambipolar hole and electron transport behavior. Herein, the electric field screening of WSe 2 with a thickness range of 1-40 layers is systemically studied by electrostatic force microscopy in combination with non-linear Thomas-Fermi theory to interpret the experimental results. The ambipolar transport behavior of 1-40 layers of WSe 2 transistors is systematically investigated with varied temperature from 300 to 5 K. The thickness-dependent transport properties (carrier mobility and Schottky barrier) are discussed. Furthermore, the surface potential of WSe 2 as a function of gate voltage is performed under Kelvin probe force microscopy to directly investigate its ambipolar behavior. The results show that the Fermi level will upshift by 100 meV when WSe 2 transmits from an insulator to an n-type semiconductor and downshift by 340 meV when WSe 2 transmits from an insulator to a p-type semiconductor. Finally, the ambipolar WSe 2 transistor-based analog circuit exhibits phase-control by gate voltage in an analog inverter, which demonstrates practical application in 2D communication electronics.

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Progress, Challenges, and Opportunities for 2D Material Based Photodetectors

Long

Wang

Fang

et al. 2018

Adv Funct Materials

961

830

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2D material based photodetectors have attracted many research projects due to their unique structures and excellent electronic and optoelectronic properties. These 2D materials, including semimetallic graphene, semiconducting black phosphorus, transition metal dichalcogenides, insulating hexagonal boron nitride, and their various heterostructures, show a wide distribution in bandgap values. To date, hundreds of photodetectors based on 2D materials have been reported. Here, a review of photodetectors based on 2D materials covering the detection spectrum from ultraviolet to infrared is presented. First, a brief insight into the detection mechanisms of 2D material photodetectors as well as introducing the figure-of-merits which are key factors for a reasonable comparison between different photodetectors is provided. Then, the recent progress on 2D material based photodetectors is reviewed. Particularly, the excellent performances such as broadband spectrum detection, ultrahigh photoresponsivity and sensitivity, fast response speed and high bandwidth, polarization-sensitive detection are pointed out on the basis of the state-of-the-art 2D photodetectors. Initial applications based on 2D material photodetectors are mentioned. Finally, an outlook is delivered, the challenges and future directions are discussed, and general advice for designing and realizing novel high-performance photodetectors is given to provide a guideline for the future development of this fast-developing field.The ORCID identification number(s) for the author(s) of this article can be found under https://doi.org/10.1002/adfm.201803807. atomic layer, while these atomically thin layers are bonded together by weak van der Waals interactions along the third dimension perpendicular to the 2D plane. The weak interlayer interaction makes it possible to exfoliate bulk crystals into isolated thin 2D flakes and even a single atomically thin layer.A photodetector is a device that can convert a light signal into an electrical signal. High performance photodetectors play important roles in many fields of our daily life, including electro-optical displays, imaging, environment monitoring, optical communication, military, security checking and so forth. 2D materials, as one of most competitive materials for designing photodetectors, have been demonstrated with remarkable characteristics, including broad detection waveband covering the wavelengths from UV to terahertz frequencies (THz, 10 12 Hz), ultrahigh photoresponsivity, polarization sensitive photodetection, high-speed photoresponse, high spatially resolved imaging, etc. Thanks to the recently developed dry transfer technique, [1] various heterostructures based on 2D materials have been designed and fabricated with desirable band alignments. Photodetectors based on these heterostructures have exhibited enhanced performances like high photovoltaic external quantum efficiency up to 30% for graphene-WS 2 -graphene, [2] ultrahigh photoresponsivity up to ≈10 10 A W −1 for graphene-MoS 2 , [3] ultrahigh photogain ...

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High Mobility 2D Palladium Diselenide Field‐Effect Transistors with Tunable Ambipolar Characteristics

Cited by 273 publications

References 46 publications

Anisotropic Growth and Scanning Tunneling Microscopy Identification of Ultrathin Even‐Layered PdSe₂ Ribbons

Anisotropic Growth and Scanning Tunneling Microscopy Identification of Ultrathin Even‐Layered PdSe₂ Ribbons

The ambipolar transport behavior of WSe2 transistors and its analogue circuits

Progress, Challenges, and Opportunities for 2D Material Based Photodetectors

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High Mobility 2D Palladium Diselenide Field‐Effect Transistors with Tunable Ambipolar Characteristics

Cited by 273 publications

References 46 publications

Anisotropic Growth and Scanning Tunneling Microscopy Identification of Ultrathin Even‐Layered PdSe2 Ribbons

Anisotropic Growth and Scanning Tunneling Microscopy Identification of Ultrathin Even‐Layered PdSe2 Ribbons

The ambipolar transport behavior of WSe2 transistors and its analogue circuits

Progress, Challenges, and Opportunities for 2D Material Based Photodetectors

Contact Info

Product

Resources

About

Anisotropic Growth and Scanning Tunneling Microscopy Identification of Ultrathin Even‐Layered PdSe₂ Ribbons

Anisotropic Growth and Scanning Tunneling Microscopy Identification of Ultrathin Even‐Layered PdSe₂ Ribbons