Graphene-on-Diamond Devices with Increased Current-Carrying Capacity: Carbon sp<sup>2</sup>-on-sp<sup>3</sup> Technology

Yu, Jie; Liu, Guanxiong; Sumant, Anirudha V.; Goyal, Vivek K; Balandin, Alexander A.

doi:10.1021/nl204545q

Cited by 177 publications

(129 citation statements)

References 39 publications

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“…[20] Both these materials have an electric current capacity of 10 9 A cm −2 . [21,22] The thermal conductivity of graphene, up to 5 300 Wm −1 K −1 at room temperature, is greater than for CNTs with a value of 3 500 Wm −1 K −1 . [23,24] Graphene also has a low visible light absorption of 2.3% per carbon-atom sheet.…”

Section: Introductionmentioning

confidence: 97%

All‐Carbon Thin‐Film Transistors as a Step Towards Flexible and Transparent Electronics

Sun

Liu

Ren

et al. 2016

Adv Elect Materials

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silicon wafer, TFTs can be fabricated on various types of rigid or flexible substrates. [1] TFTs fabricated on glass are primarily used for driving circuits in the liquid-crystal displays of televisions, computer monitors, and mobile phones, etc. Well-established TFT technologies based on amorphous silicon and polycrystalline silicon are well-suited for large-area, highresolution panels, e.g., six pieces of 65-and 75-inch TFT arrays can be fabricated on a 10.5th generation glass substrate. [2] However, TFTs based on these silicon-based semiconductors still face challenges in flexible and transparent applications, which would allow circuit integration on curved and non-rigid surfaces and in multi-layer packaging, e.g., head-up displays on windshields, informational displays on eyeglasses and transparent electronic skin in wearable electronics. [3] In terms of the materials used to construct flexible and transparent devices, not only the transistor channel but also the dielectric layers and metallic interconnects should have excellent flexibility and transparency. [4] The following factors play critical roles in the selection of channel materials: carrier mobility, temperature of material preparation, flexibility, large area availability, cost and stability. Carrier mobility is an important parameter to characterize the drift velocity of electrons or holes in a semiconductor under an applied electric field. [5] A high mobility corresponds to a high operating speed of the TFTs and their circuits. The only advantage of low-temperature polycrystalline silicon is its relatively high mobility. [6] Amorphous oxide semiconductors, including indium gallium zinc oxide, have a modest mobility and are costly due to the use of noble metal elements. [7] Hydrogenterminated amorphous silicon has modest properties in carrier mobility, large-area and flexibility, [1] and organic semiconductors are better suited for flexible and transparent TFTs except for their shortcomings of low mobility and poor environmental stability. [8] On the other hand, normal metal electrodes, such as gold, silver, aluminum and copper, cannot be used to form transparent electrodes due to their poor light transmittance. Both transparent indium tin oxide (ITO) electrodes and opaque metal electrodes suffer from flexibility constraints and can usually tolerate strains of less than 2%. [9][10][11] Therefore, the discovery of new types of robust channel and electrode materials is essential to achieve transparent, flexible, and even stretchable electronics. [12] Carbon nanomaterials, such as carbon nanotubes (CNTs) and graphene, have attracted great attention for potential use in flexible and transparent electronics since their discovery in the last two decades, [13,14] owing to their excellent properties Carbon nanotubes and graphene have attracted great attention for potential applications in flexible and transparent electronics, owing to their exceptional properties including very high electrical conductivity, optical transmittance, mechanical strength and f...

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Section: Introductionmentioning

confidence: 97%

All‐Carbon Thin‐Film Transistors as a Step Towards Flexible and Transparent Electronics

Sun

Liu

Ren

et al. 2016

Adv Elect Materials

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“…The superior electrical conductivity of graphene, for example, has been exploited to create interconnects for nanoelectronic circuits that outperform their copper counterparts. 1,2 Going forward, the challenge in leveraging these materials for commercial applications is twofold: First is the ability to devise methods of synthesis that are scalable and controllable; second, and equally important, is the ability to characterize the properties of the synthesized nanostructures, which often differ significantly from the properties of bulk materials. Materials characterization at the nanoscale requires the atomic spatial resolution possible with techniques such as atomic force microscopy, electron microscopy, X-ray diffraction, and others.…”

mentioning

confidence: 99%

The c-axis thermal conductivity of graphite film of nanometer thickness measured by time resolved X-ray diffraction

Harb¹,

Schmising²,

Enquist³

et al. 2012

Applied Physics Letters

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We report on the use of time resolved X-ray diffraction to measure the dynamics of strain in laser-excited graphite film of nanometer thickness, obtained by chemical vapour deposition (CVD). Heat transport in the CVD film is simulated with a 1-dimensional heat diffusion model. We find the experimental data to be consistent with a c-axis thermal conductivity of ∼0.7 W m−1 K−1. This value is four orders of magnitude lower than the thermal conductivity in-plane, confirming recent theoretical calculations of the thermal conductivity of multilayer graphene.

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“…Individual gas flows in the precursor gas mixture were 3 sccm CH4/160 sccm Ar/40 sccm N2. [7]); forth precursor gas N2 is added to achieve nitrogen incorporation in UNCD. (b) A Raman spectrum of the resulting film.…”

Section: Sample Synthesismentioning

confidence: 99%

Ultrananocrystalline diamond films as a high QE photocathode

Baryshev¹,

Antipov²,

Jing³

et al. 2016

AIP Conference Proceedings

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Graphene-on-Diamond Devices with Increased Current-Carrying Capacity: Carbon sp²-on-sp³ Technology

Cited by 177 publications

References 39 publications

All‐Carbon Thin‐Film Transistors as a Step Towards Flexible and Transparent Electronics

All‐Carbon Thin‐Film Transistors as a Step Towards Flexible and Transparent Electronics

The c-axis thermal conductivity of graphite film of nanometer thickness measured by time resolved X-ray diffraction

Ultrananocrystalline diamond films as a high QE photocathode

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Graphene-on-Diamond Devices with Increased Current-Carrying Capacity: Carbon sp2-on-sp3 Technology

Cited by 177 publications

References 39 publications

All‐Carbon Thin‐Film Transistors as a Step Towards Flexible and Transparent Electronics

All‐Carbon Thin‐Film Transistors as a Step Towards Flexible and Transparent Electronics

The c-axis thermal conductivity of graphite film of nanometer thickness measured by time resolved X-ray diffraction

Ultrananocrystalline diamond films as a high QE photocathode

Contact Info

Product

Resources

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Graphene-on-Diamond Devices with Increased Current-Carrying Capacity: Carbon sp²-on-sp³ Technology