Fully Transparent p‐MoTe2 2D Transistors Using Ultrathin MoOx/Pt Contact Media for Indium‐Tin‐Oxide Source/Drain

Cho, Yongjae; Park, Ji Hoon; Kim, Min-Ju; Jeong, Yeonsu; Ahn, Jongtae; Kim, Tae‐Young; Choi, Hyunyong; Yi, Yeonjin; Im, Seongil

doi:10.1002/adfm.201801204

Cited by 28 publications

(20 citation statements)

References 44 publications

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“…The transition metal oxide interlayer, inserted between the electrode and the active layer, has been widely used for this purpose in organic and quantum dot solar cells. − This n -type oxide layer injects electrons into the valence band of the active layer, effectively extracting positively charged holes. − However, the approach using such an interlayer to improve the photovoltaic performances in 2D TMD heterojunctions has not yet been demonstrated. In addition, the previous reports used the vacuum deposition and O 2 plasma processes to insert the oxide layer, which can damage the active layer and cause performance degradation. − In this study, we propose the monolithic fabrication of tungsten oxide (WO x ) for use as a hole extraction layer in the WSe 2 –MoS 2 p – n heterojunctions. The formation of a WO x /WSe 2 junction by the monolithic oxidation induces the effective tuning of the Fermi level ( E F ) of WSe 2 and promotes hole extraction through favorable band alignments at the heterointerface.…”

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Monolithic Interface Contact Engineering to Boost Optoelectronic Performances of 2D Semiconductor Photovoltaic Heterojunctions

et al. 2020

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In optoelectronic devices based on two-dimensional (2D) semiconductor heterojunctions, the efficient charge transport of photogenerated carriers across the interface is a critical factor to determine the device performances. Here, we report an unexplored approach to boost the optoelectronic device performances of the WSe2–MoS2 p–n heterojunctions via the monolithic-oxidation-induced doping and resultant modulation of the interface band alignment. In the proposed device, the atomically thin WO x layer, which is directly formed by layer-by-layer oxidation of WSe2, is used as a charge transport layer for promoting hole extraction. The use of the ultrathin oxide layer significantly enhanced the photoresponsivity of the WSe2–MoS2 p–n junction devices, and the power conversion efficiency increased from 0.7 to 5.0%, maintaining the response time. The enhanced characteristics can be understood by the formation of the low Schottky barrier and favorable interface band alignment, as confirmed by band alignment analyses and first-principle calculations. Our work suggests a new route to achieve interface contact engineering in the heterostructures toward realizing high-performance 2D optoelectronics.

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Monolithic Interface Contact Engineering to Boost Optoelectronic Performances of 2D Semiconductor Photovoltaic Heterojunctions

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“…Possible contact improvement methods such as O 2 plasma treatment of p-MoTe 2 surface before Pt contact could be conducted for future work to improve the memory cell performances. [46] For main primary application of our complementary type cell (inset circuits), nonvolatile FeNVM www.advelectronicmat.de of 100 mV is applied, output voltage signals were measured to be 80 mV and 0 V for PROGRAM and ERASE by ±20 V 1 s pulses, respectively as shown in Figure 4d. Those two output voltage states were maintained for more than 500 s according to another retention measurement.…”

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Complementary Type Ferroelectric Memory Transistor Circuits with P‐ and N‐Channel MoTe₂

Hong

Kim

Cho

et al. 2020

Adv Elect Materials

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Ferroelectric nonvolatile memory (FeNVM) field effect transistors (FETs) are reported using p‐channel MoTe2 and P(VDF‐TrFE) ferroelectric polymer, and furthermore a complementary type memory cell is demonstrated coupling p‐ and n‐channel MoTe2 FETs. A top‐gate p‐FET with P(VDF‐TrFE) and a bottom‐gate n‐FET with Al2O3 dielectric are integrated as one cell. Such a complementary type cell is more desirable research path in respect of power consumption but rare to find in 2D‐based memory reports. Among many 2D semiconductors MoTe2 is selected, because p‐type MoTe2‐based FeNVM is not reported yet, and also because it is relatively easy to obtain both p‐ and n‐channel from the homogeneous MoTe2. The integrated device also operates as a complementary metal oxide semiconductor inverter in a small voltage range from 0 to ≈2.5 V, but primarily works as a FeNVM circuit when p‐channel with top P(VDF‐TrFE) is biased with high voltages over the coercive electric field (Ec) of the polymer. The bottom gate n‐channel transistor operates as a switching device in the FeNVM cell, allowing voltage output signals during device operations. It is concluded that the complementary type FeNVM cell is practical and novel enough to report as a first time demonstration based on 2D MoTe2.

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“…Although we could not resolve the trap DOS at the heterojunction interface even in HRSTEM images, the trap DOS can be analytically depicted with each device condition and its corresponding band diagrams as respectively shown in Figure a–c and d–f. , Parts b and e of Figure show the initial pristine case of our stacked channel FET without gate pulse. The band diagram in Figure e describes the source and drain contacting WSe 2 , which interfaces with MoTe 2 .…”

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Nonvolatile and Neuromorphic Memory Devices Using Interfacial Traps in Two-Dimensional WSe₂/MoTe₂ Stack Channel

et al. 2020

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Very recently, stacked two-dimensional materials have been studied, focusing on the van der Waals interaction at their stack junction interface. Here, we report field effect transistors (FETs) with stacked transition metal dichalcogenide (TMD) channels, where the heterojunction interface between two TMDs appears useful for nonvolatile or neuromorphic memory FETs. A few nanometer-thin WSe2 and MoTe2 flakes are vertically stacked on the gate dielectric, and bottom p-MoTe2 performs as a channel for hole transport. Interestingly, the WSe2/MoTe2 stack interface functions as a hole trapping site where traps behave in a nonvolatile manner, although trapping/detrapping can be controlled by gate voltage (V GS). Memory retention after high V GS pulse appears longer than 10000 s, and the Program/Erase ratio in a drain current is higher than 200. Moreover, the traps are delicately controllable even with small V GS, which indicates that a neuromorphic memory is also possible with our heterojunction stack FETs. Our stack channel FET demonstrates neuromorphic memory behavior of ∼94% recognition accuracy.

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Fully Transparent p‐MoTe₂ 2D Transistors Using Ultrathin MoO_x/Pt Contact Media for Indium‐Tin‐Oxide Source/Drain

Cited by 28 publications

References 44 publications

Monolithic Interface Contact Engineering to Boost Optoelectronic Performances of 2D Semiconductor Photovoltaic Heterojunctions

Monolithic Interface Contact Engineering to Boost Optoelectronic Performances of 2D Semiconductor Photovoltaic Heterojunctions

Complementary Type Ferroelectric Memory Transistor Circuits with P‐ and N‐Channel MoTe₂

Nonvolatile and Neuromorphic Memory Devices Using Interfacial Traps in Two-Dimensional WSe₂/MoTe₂ Stack Channel

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Fully Transparent p‐MoTe2 2D Transistors Using Ultrathin MoOx/Pt Contact Media for Indium‐Tin‐Oxide Source/Drain

Cited by 28 publications

References 44 publications

Monolithic Interface Contact Engineering to Boost Optoelectronic Performances of 2D Semiconductor Photovoltaic Heterojunctions

Monolithic Interface Contact Engineering to Boost Optoelectronic Performances of 2D Semiconductor Photovoltaic Heterojunctions

Complementary Type Ferroelectric Memory Transistor Circuits with P‐ and N‐Channel MoTe2

Nonvolatile and Neuromorphic Memory Devices Using Interfacial Traps in Two-Dimensional WSe2/MoTe2 Stack Channel

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Fully Transparent p‐MoTe₂ 2D Transistors Using Ultrathin MoO_x/Pt Contact Media for Indium‐Tin‐Oxide Source/Drain

Complementary Type Ferroelectric Memory Transistor Circuits with P‐ and N‐Channel MoTe₂

Nonvolatile and Neuromorphic Memory Devices Using Interfacial Traps in Two-Dimensional WSe₂/MoTe₂ Stack Channel