Field Effect Transistor Sensors Based on In‐Plane 1T′/2H/1T′ MoTe<sub>2</sub> Heterophases with Superior Sensitivity and Output Signals

Zhang, Shichao; Wu, You; Gao, Feng; Shang, Huiming; Zhang, Jia; Li, Zhonghua; Fu, Yongqing; Hu, PingAn

doi:10.1002/adfm.202205299

Cited by 25 publications

(20 citation statements)

References 46 publications

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“…In order to address these issues, the following strategies have been proposed: (1) doping the semiconductors to reduce the Schottky barrier width so that the tunneling current exceeds the thermal ion emission current; this is a common method used in the electrical industry at present; [19][20][21][22] (2) changing the SBH by applying strain; for instance, a transition from the Schottky contact to the Ohmic contact occurs in the MoSSe/Ge heterobilayer under tensile strain; 23 (3) employing 2D metals instead of bulk phases as electrodes to suppress the MIGSs; thus, the FLP can be eliminated; [24][25][26][27] (4) phase engineering to reduce the total charge injection barrier, and the phase transformation from semiconductors to metals can reduce the potential barrier of the contacts; [28][29][30] and (5) breaking the vdW gap through an edge-contact geometry. [30][31][32][33] However, how to reduce the contact resistance using feasible strategies, stable performance and wide versatility remains an open question because the above strategies all have inevitable shortcomings.…”

Section: Introductionmentioning

confidence: 99%

Ohmic contacts of the two-dimensional Ca₂N/MoS₂donor–acceptor heterostructure

Wang

et al. 2023

Phys. Chem. Chem. Phys.

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Section: Introductionmentioning

confidence: 99%

Ohmic contacts of the two-dimensional Ca₂N/MoS₂donor–acceptor heterostructure

Wang

et al. 2023

Phys. Chem. Chem. Phys.

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“…They employed the transfer length method to calculate a contact resistance of 470 ± 30 Ω•μm for the 1T′ electrodes. 18 Similarly, Hu and his team employed a phase-selective growth technique to spatially combine 2H MoTe 2 and 1T′ MoTe 2 , resulting in field-effect transistors (FETs) that demonstrated a low contact resistance of 7.1 kΩ•μm at an on-state voltage of −60 V. 19 Jiao and his team created the 1T′/2H MoTe 2 heterostructured shortchannel bilayer field-effect devices using a one-step CVD process, which led to a reduced electrode barrier height of 20 meV and a room-temperature mobility of 130 cm 2 V −1 s −1 . 20 All of these studies have relied on the progress of chemical vapor deposition (CVD) 21 despite the presence of similar initiatives.…”

Section: ■ Introductionmentioning

confidence: 99%

Broad-Band Photodetector Based on a Lateral MoTe₂ 1T-2H-1T Homojunction

Ding,

Qi,

Wang

et al. 2023

J. Phys. Chem. C

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The use of a two-dimensional (2D) layered molybdenum ditelluride (MoTe 2 ) nanosheet in electronic devices can be enhanced by transforming its electrode to a metallic phase, forming a 1T-2H-1T heterogeneous structure. This, however, leads to the formation of a junction between the electrode and the channel which can reduce the effectiveness of the device. To address this issue, this paper proposes a novel method of creating 1T-2H-1T MoTe 2 optoelectronic devices using oxygen mild plasma preparation. Transmission electron microscopy testing and first-principles calculations have confirmed that this treatment results in the loss of some Te atoms, thus lowering their energy bands and creating metallic properties. The electrical and optoelectronic performance testing at varying temperatures and wavelengths has revealed improved mobility and responsiveness, with a maximum mobility of 30 cm 2 /V s and a responsivity of 0.6 A/W under a 940 nm laser irradiation, being 25 times higher than the intrinsic one. This research provides an efficient phase engineering technique for the accurate and undamaged fabrication of optoelectronic devices using two-dimensional materials.

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“…31 Another one-step method for fabricating the in-plane 1T′/2H/1T′ MoTe 2 heterophases was phase-selective growth of specific molybdenum precursors Mo/MoO 3 (where the precursor for 1T′-MoTe 2 growth is a continuous Mo film prepared by electron beam evaporation, and the precursor for 2H-MoTe 2 growth is MoO 3 film prepared by treating Mo film with oxygen plasma). 25 Table S1 further summarized the detailed comparison of large-area fabrication parameters for different growth methods. Existing one-step methods are sensitive to the types of precursors and growth parameters.…”

mentioning

confidence: 99%

“…TMD-based 2D metal–semiconductor heterostructures exhibit ohmic contact behavior with low contact resistance, which is an effective approach for high-performance 2D electronics. , Therefore, the phase-controlled synthesis of large-scale 2D metal–semiconductor heterostructures based on TMDs shows promising applications. The existing phase-engineering methods usually suffer from poor spatial controllability, small-scale production, and poor material compatibility. − ,− In addition, most of the 2D metal–semiconductor structures suitable for large-area integration use a two-step chemical vapor deposition (CVD) growth process, − which puts forward high requirements for the secondary growth compatibility of the materials. It is in tight demand to devise a spatially controlled and scalable one-step phase-engineering growth method for directly synthesizing metal–semiconductor heterostructure arrays of TMDs.…”

mentioning

confidence: 99%

“…Recently, large-scale 1T′/2H MoTe 2 metal–semiconductor heterostrucutres were obtained by one-step tellurizing MoO 3 /MoO 2.0–2.5 patterns fabricated by a complex process (where the precursor for 1T′-MoTe 2 growth is MoO 3 film deposited by thermal evaporation, and the precursor for 2H-MoTe 2 growth is MoO 2.0–2.5 film obtained by magnetron sputtering of Mo film followed by oxidation) . Another one-step method for fabricating the in-plane 1T′/2H/1T′ MoTe 2 heterophases was phase-selective growth of specific molybdenum precursors Mo/MoO 3 (where the precursor for 1T′-MoTe 2 growth is a continuous Mo film prepared by electron beam evaporation, and the precursor for 2H-MoTe 2 growth is MoO 3 film prepared by treating Mo film with oxygen plasma) Table S1 further summarized the detailed comparison of large-area fabrication parameters for different growth methods.…”

mentioning

confidence: 99%

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One-Step Synthesis of Two-Dimensional Metal–Semiconductor Circuitry Based on W-Triggered Spatial Phase Engineering

Zeng,

Wu,

et al. 2023

ACS Materials Lett.

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Molybdenum ditelluride (MoTe2) exhibits a variety of crystal phases, which can be phase-controlled by various external means, showing broad prospects in modern integrated circuits. The structure in which the semimetal 1T′ (or Td) phase electrode contacts the semiconductor 2H phase channel is considered an elegant solution for high-performance two-dimensional (2D) circuits because it achieves low contact resistance. However, most of the 2D metal–semiconductor structures for large-area integration use a two-step growth process, which puts forward high requirements for the secondary growth compatibility of the material. Here, we develop a method for the stable synthesis of the metallic Mo x W1–x Te2 (0 < x < 1) by W-triggered spatial phase engineering, and we further obtain a large-area Mo x W1–x Te2/2H-MoTe2 in-plane metal–semiconductor structure by one-step tellurization of a MoW/Mo periodic structure. Due to the unique 2D in-plane epitaxial mechanism of the phase transition from 1T′ to 2H, the highly crystalline semiconductor 2H-MoTe2 squeezes between two metallic Mo x W1–x Te2 electrodes and forms a seamless coplanar contacted channel; thus, the fabricated field-effect transistors exhibit good electrical characteristics. In addition, large-area 2D metal–semiconductor heterostructure arrays can be transferred onto flexible substrates, showing promising applications in flexible electronics. Herein, one-step synthesis of large-area 2D in-plane metal–semiconductor arrays opens up new possibilities for future integrated high-performance logic circuits.

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Field Effect Transistor Sensors Based on In‐Plane 1T′/2H/1T′ MoTe₂ Heterophases with Superior Sensitivity and Output Signals

Cited by 25 publications

References 46 publications

Ohmic contacts of the two-dimensional Ca₂N/MoS₂donor–acceptor heterostructure

Ohmic contacts of the two-dimensional Ca₂N/MoS₂donor–acceptor heterostructure

Broad-Band Photodetector Based on a Lateral MoTe₂ 1T-2H-1T Homojunction

One-Step Synthesis of Two-Dimensional Metal–Semiconductor Circuitry Based on W-Triggered Spatial Phase Engineering

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Field Effect Transistor Sensors Based on In‐Plane 1T′/2H/1T′ MoTe2 Heterophases with Superior Sensitivity and Output Signals

Cited by 25 publications

References 46 publications

Ohmic contacts of the two-dimensional Ca2N/MoS2donor–acceptor heterostructure

Ohmic contacts of the two-dimensional Ca2N/MoS2donor–acceptor heterostructure

Broad-Band Photodetector Based on a Lateral MoTe2 1T-2H-1T Homojunction

One-Step Synthesis of Two-Dimensional Metal–Semiconductor Circuitry Based on W-Triggered Spatial Phase Engineering

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Product

Resources

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Field Effect Transistor Sensors Based on In‐Plane 1T′/2H/1T′ MoTe₂ Heterophases with Superior Sensitivity and Output Signals

Ohmic contacts of the two-dimensional Ca₂N/MoS₂donor–acceptor heterostructure

Ohmic contacts of the two-dimensional Ca₂N/MoS₂donor–acceptor heterostructure

Broad-Band Photodetector Based on a Lateral MoTe₂ 1T-2H-1T Homojunction