Single‐Crystal Statistical Field‐Effect Transistors

Kumar, Pramod; Gerchikov, Yulia; Shivananda, Kammasandra Nanajunda; Sadeh, Anat; Eichen, Yoav; Tessler, Nir

doi:10.1002/aelm.201500309

Cited by 5 publications

(5 citation statements)

References 16 publications

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“…In this way, the trap carrier density of the 1D C 60 crystal array is estimated to be as low as 3.31 × 10 −9 C cm −2 , which is 7-136 times lower than that of the C 60 crystals prepared by previously reported methods (Figure 4f and Table S1, Supporting Information). [11][12][13][14]20,[46][47][48][49][50][51][52] The excellent device performance of the OFET device could be attributed to the high crystal quality of 1D C 60 single crystal and the optimized device structure with good electrical contacts. Next, the performance uniformity of 55 C 60 crystal array-based devices on the same substrate was investigated.…”

Section: Resultsmentioning

confidence: 99%

“…Fullerene (C 60 ) and its derivatives with outstanding optoelectronic properties are identified to be promising materials to construct high-performance electronic and photonic devices, such as solar cells, [1][2][3] superconductors, [4,5] ferromagnets, [6] photodetectors, [7][8][9] tunnel transistors, [10] and organic field-effect transistors (OFETs), [11][12][13][14] owing to their highly conjugated molecular structures, [15] high electron-accepting, [16,17] and 3D electrontransporting properties. [18] Though most of the current applications rely on the use of C 60 thin films, further improvement of the device performance is hindered by the intrinsic problems in the polycrystalline thin-film systems, such as abundant grain boundaries as well as a large number of defects.…”

Section: Introductionmentioning

confidence: 99%

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Wafer‐Scale Growth of Aligned C₆₀ Single Crystals via Solution‐Phase Epitaxy for High‐Performance Transistors

Zhang

Deng

Fang

et al. 2021

Adv Funct Materials

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Fullerene (C 60 ) single crystals with exceptionally low defects and nearly perfect translational symmetry make them appealing in achieving high-performance n-type organic transistors. However, because of its natural 0D structure, control over continuous crystallization of C 60 over a large area is extremely challenging. Here, the authors report a solution-phase epitaxial approach for wafer-scale growth of continuously aligned C 60 single crystals. This method enables the rational control of the density of nucleation event at meniscus front by confining the size and shape of meniscus with a microchannel template. In this case, a single nucleus as seed crystal can be formed at the front of meniscus, and then epitaxial growth from the seed crystal occurs with continuous retreat of the meniscus. As a result, highly uniform C 60 singlecrystal array with ultralow defect density is obtained on 2-inch substrate. Organic field-effect transistors made from the C 60 single-crystal array show a high average electron mobility of 2.17 cm 2 V −1 s −1 , along with a maximum mobility of 5.09 cm 2 V −1 s −1 , which is much superior to the C 60 polycrystalline film-based devices. This strategy opens new opportunities for the scalable fabrication of high-performance integrated devices based on organic crystals.

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Section: Resultsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Wafer‐Scale Growth of Aligned C₆₀ Single Crystals via Solution‐Phase Epitaxy for High‐Performance Transistors

Zhang

Deng

Fang

et al. 2021

Adv Funct Materials

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“…A general-purpose 2D finite-element simulator (ATLAS, Silvaco) was employed for a physical and numerical investigation into OTFTs. This simulation tool performs selfconsistent calculation of solutions to coupled Poisson's and drift-diffusion equation over a user-defined 2D discrete mesh [14][15][16][17][18]. The Schottky model for metal electrodes is included to dictate contact effects in OTFTs.…”

Section: Simulation Methodsmentioning

confidence: 99%

Key factors affecting contact resistance in coplanar organic thin-film transistors

Jo¹,

Cho²,

Kim³

2022

J. Phys. D: Appl. Phys.

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We present a comprehensive numerical analysis of contact resistance in coplanar organic thin-film transistors. A large number of hole-transporting organic transistors are investigated through two-dimensional finite-element simulation, by deliberately changing the channel length, source/drain electrode thickness, and hole-injection energy barrier heights. Gate-field-dependent terminal contact resistances of these devices are fully estimated and electrostatic distributions inside the organic semiconductor film are visualized for the understanding of physical mechanisms. It is found that the relationship between source/drain electrode thickness and contact resistance does not follow any simple trend and is also strongly associated with the injection energy barrier. Moreover, the origin of negative contact resistance in organic transistors featuring a minimal charge-injection barrier is elaborated. Finally, a direct impact of the semiconductor charge-carrier mobility on contact resistance is addressed, revealing a linear dependence of contact resistance on inverse mobility over a broad parameter range.

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“…In this case, the overall charge transport is limited by inter-domain transport, and graphene blended into a film can effectively solve this problem by forming highly conductive inter-domain pathways. Previously reported statistical transistors where metallic islands passivate disconnected crystals or FETs with a carbon-nanotube/polymer hybrid channel showed similar benefits from enhanced connectivity or percolation [ 51 , 52 ]. However, it is important to note that, especially for transistor applications, care has to be taken not to make the entire channel too metallic (i.e., on-off ratio compromised).…”

Section: Hybridization Strategiesmentioning

confidence: 99%

Nanostructured Graphene: An Active Component in Optoelectronic Devices

Kim

2018

Nanomaterials

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Nanostructured and chemically modified graphene-based nanomaterials possess intriguing properties for their incorporation as an active component in a wide spectrum of optoelectronic architectures. From a technological point of view, this aspect brings many new opportunities to the now well-known atomically thin carbon sheet, multiplying its application areas beyond transparent electrodes. This article gives an overview of fundamental concepts, theoretical backgrounds, design principles, technological implications, and recent advances in semiconductor devices that integrate nanostructured graphene materials into their active region. Starting from the unique electronic nature of graphene, a physical understanding of finite-size effects, non-idealities, and functionalizing mechanisms is established. This is followed by the conceptualization of hybridized films, addressing how the insertion of graphene can modulate or improve material properties. Importantly, it provides general guidelines for designing new materials and devices with specific characteristics. Next, a number of notable devices found in the literature are highlighted. It provides practical information on material preparation, device fabrication, and optimization for high-performance optoelectronics with a graphene hybrid channel. Finally, concluding remarks are made with the summary of the current status, scientific issues, and meaningful approaches to realizing next-generation technologies.

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Single‐Crystal Statistical Field‐Effect Transistors

Cited by 5 publications

References 16 publications

Wafer‐Scale Growth of Aligned C₆₀ Single Crystals via Solution‐Phase Epitaxy for High‐Performance Transistors

Wafer‐Scale Growth of Aligned C₆₀ Single Crystals via Solution‐Phase Epitaxy for High‐Performance Transistors

Key factors affecting contact resistance in coplanar organic thin-film transistors

Nanostructured Graphene: An Active Component in Optoelectronic Devices

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Single‐Crystal Statistical Field‐Effect Transistors

Cited by 5 publications

References 16 publications

Wafer‐Scale Growth of Aligned C60 Single Crystals via Solution‐Phase Epitaxy for High‐Performance Transistors

Wafer‐Scale Growth of Aligned C60 Single Crystals via Solution‐Phase Epitaxy for High‐Performance Transistors

Key factors affecting contact resistance in coplanar organic thin-film transistors

Nanostructured Graphene: An Active Component in Optoelectronic Devices

Contact Info

Product

Resources

About

Wafer‐Scale Growth of Aligned C₆₀ Single Crystals via Solution‐Phase Epitaxy for High‐Performance Transistors

Wafer‐Scale Growth of Aligned C₆₀ Single Crystals via Solution‐Phase Epitaxy for High‐Performance Transistors