Rui Cheng scite author profile

Two-dimensional layered semiconductors such as MoS₂ and WSe₂ have attracted considerable interest in recent times. Exploring the full potential of these layered materials requires precise spatial modulation of their chemical composition and electronic properties to create well-defined heterostructures. Here, we report the growth of compositionally modulated MoS₂-MoSe₂ and WS₂-WSe₂ lateral heterostructures by in situ modulation of the vapour-phase reactants during growth of these two-dimensional crystals. Raman and photoluminescence mapping studies demonstrate that the resulting heterostructure nanosheets exhibit clear structural and optical modulation. Transmission electron microscopy and elemental mapping studies reveal a single crystalline structure with opposite modulation of sulphur and selenium distributions across the heterostructure interface. Electrical transport studies demonstrate that the WSe₂-WS₂ heterojunctions form lateral p-n diodes and photodiodes, and can be used to create complementary inverters with high voltage gain. Our study is an important advance in the development of layered semiconductor heterostructures, an essential step towards achieving functional electronics and optoelectronics.

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Electroluminescence and Photocurrent Generation from Atomically Sharp WSe₂/MoS₂ Heterojunction p–n Diodes

Cheng

et al. 2014

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The p–n diodes represent the most fundamental device building blocks for diverse optoelectronic functions, but are difficult to achieve in atomically thin transition metal dichalcogenides (TMDs) due to the challenges in selectively doping them into p- or n-type semiconductors. Here, we demonstrate that an atomically thin and sharp heterojunction p–n diode can be created by vertically stacking p-type monolayer tungsten diselenide (WSe2) and n-type few-layer molybdenum disulfide (MoS2). Electrical measurements of the vertically staked WSe2/MoS2 heterojunctions reveal excellent current rectification behavior with an ideality factor of 1.2. Photocurrent mapping shows rapid photoresponse over the entire overlapping region with a highest external quantum efficiency up to 12%. Electroluminescence studies show prominent band edge excitonic emission and strikingly enhanced hot-electron luminescence. A systematic investigation shows distinct layer-number dependent emission characteristics and reveals important insight about the origin of hot-electron luminescence and the nature of electron–orbital interaction in TMDs. We believe that these atomically thin heterojunction p–n diodes represent an interesting system for probing the fundamental electro-optical properties in TMDs and can open up a new pathway to novel optoelectronic devices such as atomically thin photodetectors, photovoltaics, as well as spin- and valley-polarized light emitting diodes, on-chip lasers.

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High-speed graphene transistors with a self-aligned nanowire gate

Liao

Lin

Bao

et al. 2010

Nature

1,214

850

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Graphene has attracted considerable interest as a potential new electronic material [1][2][3][4][5][6][7][8][9][10][11] . With its high carrier mobility, graphene is of particular interest for ultrahigh-speed radio-frequency electronics [12][13][14][15][16][17][18] . However, conventional device fabrication processes cannot readily be applied to produce high-speed graphene transistors because they often introduce significant defects into the monolayer of carbon lattices and severely degrade the device performance [19][20][21] . Here we report an approach to the fabrication of high-speed graphene transistors with a self-aligned nanowire gate to prevent such degradation. A Co 2 Si-Al 2 O 3 core-shell nanowire is used as the gate, with the source and drain electrodes defined through a self-alignment process and the channel length defined by the nanowire diameter. The physical assembly of the nanowire gate preserves the high carrier mobility in graphene, and the selfalignment process ensures that the edges of the source, drain and gate electrodes are automatically and precisely positioned so that no overlapping or significant gaps exist between these electrodes, thus minimizing access resistance. It therefore allows for transistor performance not previously possible. Graphene transistors with a channel length as low as 140 nm have been fabricated with the highest scaled on-current (3.32 mA mm 21 ) and transconductance (1.27 mS mm 21 ) reported so far. Significantly, on-chip microwave measurements demonstrate that the self-aligned devices have a high intrinsic cut-off (transit) frequency of f T 5 100-300 GHz, with the extrinsic f T (in the range of a few gigahertz) largely limited by parasitic pad capacitance. The reported intrinsic f T of the graphene transistors is comparable to that of the very best high-electron-mobility transistors with similar gate lengths 10 .With the highest carrier mobility, exceeding 200,000 cm 2 V 21 s 21 (ref. 8), and many other desirable properties, including a large critical current density (,2 3 10 8 A cm 22 (ref. 22)) and a high saturation velocity (5.5 3 10 7 cm s 21 (ref. 11)), graphene has significant potential for high-speed electronics to offer excellent radio-frequency characteristics with very high cut-off frequency (f T ). Importantly, recent studies have demonstrated graphene transistors operating in the gigahertz regime [12][13][14][16][17][18] with a record of f T 5 100 GHz (ref. 13). However, the reported radio-frequency performance so far is still far from the potential that the graphene transistors may offer, and is primarily limited by two adverse factors in the device fabrication process.The first limitation is associated with the severe mobility degradation resulting from the graphene-dielectric integration process, which introduces substantial defects into pristine graphene lattices 20,23 . To overcome this, we have recently developed a strategy to integrate high-quality, high-dielectric-constant dielectrics with graphene using a physical assembly approach without in...

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Plasmon resonance enhanced multicolour photodetection by graphene

et al. 2011

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Graphene has the potential for high-speed, wide-band photodetection, but only with very low external quantum efficiency and no spectral selectivity. Here we report a dramatic enhancement of the overall quantum efficiency and spectral selectivity that enables multicolour photodetection, by coupling graphene with plasmonic nanostructures. We show that metallic plasmonic nanostructures can be integrated with graphene photodetectors to greatly enhance the photocurrent and external quantum efficiency by up to 1,500%. Plasmonic nanostructures of variable resonance frequencies selectively amplify the photoresponse of graphene to light of different wavelengths, enabling highly specific detection of multicolours. Being atomically thin, graphene photodetectors effectively exploit the local plasmonic enhancement effect to achieve a significant enhancement factor not normally possible with traditional planar semiconductor materials.

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Chemical vapour deposition growth of large single crystals of monolayer and bilayer graphene

et al. 2013

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Rui Cheng

Lateral epitaxial growth of two-dimensional layered semiconductor heterojunctions

Electroluminescence and Photocurrent Generation from Atomically Sharp WSe₂/MoS₂ Heterojunction p–n Diodes

High-speed graphene transistors with a self-aligned nanowire gate

Plasmon resonance enhanced multicolour photodetection by graphene

Chemical vapour deposition growth of large single crystals of monolayer and bilayer graphene

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Rui Cheng

Lateral epitaxial growth of two-dimensional layered semiconductor heterojunctions

Electroluminescence and Photocurrent Generation from Atomically Sharp WSe2/MoS2 Heterojunction p–n Diodes

High-speed graphene transistors with a self-aligned nanowire gate

Plasmon resonance enhanced multicolour photodetection by graphene

Chemical vapour deposition growth of large single crystals of monolayer and bilayer graphene

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Product

Resources

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Electroluminescence and Photocurrent Generation from Atomically Sharp WSe₂/MoS₂ Heterojunction p–n Diodes