Correlation between Crystal Structure and Mobility in Organic Field-Effect Transistors Based on Single Crystals of Tetrathiafulvalene Derivatives

Mas‐Torrent, Marta; Hadley, P.; Bromley, Stefan T.; Ribas, Xavi; Tarrés, Judit; Mas, M.; Molins, Elı́es; Veciana, Jaume; Rovira, Concepció

doi:10.1021/ja048342i

Cited by 275 publications

(259 citation statements)

References 44 publications

(74 reference statements)

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“…To the best of our knowledge, this is the highest mobility for n-channel transistors based on organic single crystal wires prepared by solution processing. It is comparable with the highest mobility of p-channel organic wires prepared by solution processing (20)(21)(22), as well as to the best performance of n-channel single-crystal organic transistors prepared with a free-space gate dielectric (43). Additionally, this mobility is approximately 10 times higher than that of vacuum-evaporated thin-film devices (0.1 cm 2 /Vs) of the same molecules (39).…”

Section: (See Materials and Methods)supporting

confidence: 56%

“…These unique materials combine the high-performance of singlecrystalline structures with solution-processability by dispersion (17,18). Several p-channel (hole-transporting) organic wires prepared by solution-processing have exhibited Ͼ 0.1 cm 2 /Vs for singlewire transistors (19)(20)(21)(22), whereas only a few solution-synthesized n-channel organic wires have been reported, typically with low performance ( Ϸ10 Ϫ3 Ϫ 10 Ϫ2 cm 2 /Vs) (23,24).Despite the intrinsic high mobility of single-crystalline wires, precise wire placement and wire-to-wire performance variation, due to the difference in the contact quality at the wire/insulator and wire/electrode interfaces, substantially hinder successful device integration (10, 25). Therefore, the technology to achieve network films of organic MWs deposited from a dispersion with controlled alignment and density is acutely desired.…”

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confidence: 99%

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Solution-processed, high-performance n-channel organic microwire transistors

Oh¹,

Lee²,

Mannsfeld³

et al. 2009

Proc. Natl. Acad. Sci. U.S.A.

221

197

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The development of solution-processable, high-performance nchannel organic semiconductors is crucial to realizing low-cost, all-organic complementary circuits. Single-crystalline organic semiconductor nano/microwires (NWs/MWs) have great potential as active materials in solution-formed high-performance transistors. However, the technology to integrate these elements into functional networks with controlled alignment and density lags far behind their inorganic counterparts. Here, we report a solutionprocessing approach to achieve high-performance air-stable nchannel organic transistors (the field-effect mobility ( ) up to 0.24 cm 2 /Vs for MW networks) comprising high mobility, solutionsynthesized single-crystalline organic semiconducting MWs ( as high as 1.4 cm 2 /Vs for individual MWs) and a filtration-and-transfer (FAT) alignment method. The FAT method enables facile control over both alignment and density of MWs. Our approach presents a route toward solution-processed, high-performance organic transistors and could be used for directed assembly of various functional organic and inorganic NWs/MWs. organic semiconductors ͉ single crystals ͉ solution processing ͉ alignment S olution-processable, high-performance n-channel (electrontransporting) organic semiconductors are indispensable for cost-effective production of all-organic, flexible complementary logic elements (1-3). To date, however, very few solutionprocessable, air-stable organic n-channel semiconductors matching the performance of amorphous silicon (a-Si) ( Ն 0.1 cm 2 /Vs) have been reported (4-8). Organic semiconductor nano/microwires (NWs/MWs) have recently emerged as promising building blocks for various electronic and optical applications such as light-emitting diodes (LEDs) (9), field-effect transistors (FETs) (10), photoswitches (11), vapor sensors (12), solar cells (13), nanoscale lasers (14), optical waveguides (15), and memory devices (16). These unique materials combine the high-performance of singlecrystalline structures with solution-processability by dispersion (17,18). Several p-channel (hole-transporting) organic wires prepared by solution-processing have exhibited Ͼ 0.1 cm 2 /Vs for singlewire transistors (19)(20)(21)(22), whereas only a few solution-synthesized n-channel organic wires have been reported, typically with low performance ( Ϸ10 Ϫ3 Ϫ 10 Ϫ2 cm 2 /Vs) (23,24).Despite the intrinsic high mobility of single-crystalline wires, precise wire placement and wire-to-wire performance variation, due to the difference in the contact quality at the wire/insulator and wire/electrode interfaces, substantially hinder successful device integration (10, 25). Therefore, the technology to achieve network films of organic MWs deposited from a dispersion with controlled alignment and density is acutely desired. The integration of inorganic and metallic wires into functional network films has been extensively explored by using a number of methods such as the flow cell method (26), electric field (27, 28), magnetic field (29), electrospinning (30),...

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Section: (See Materials and Methods)supporting

confidence: 56%

mentioning

confidence: 99%

mentioning

confidence: 99%

See 1 more Smart Citation

Solution-processed, high-performance n-channel organic microwire transistors

Oh¹,

Lee²,

Mannsfeld³

et al. 2009

Proc. Natl. Acad. Sci. U.S.A.

221

197

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“…It was pointed out that the higher solubility of these materials should be advantageous for their use in low-cost solution processing [57]. In fact, SC-OFETs were fabricated by solution processing for some kinds of TTF analogues [64][65][66][67].…”

Section: Sc-ofets Of Ttf Analoguesmentioning

confidence: 99%

Organic field-effect transistors using single crystals

Hasegawa

Takeya

2009

Science and Technology of Advanced Materials

348

215

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Organic field-effect transistors using small-molecule organic single crystals are developed to investigate fundamental aspects of organic thin-film transistors that have been widely studied for possible future markets for 'plastic electronics'. In reviewing the physics and chemistry of single-crystal organic field-effect transistors (SC-OFETs), the nature of intrinsic charge dynamics is elucidated for the carriers induced at the single crystal surfaces of molecular semiconductors. Materials for SC-OFETs are first reviewed with descriptions of the fabrication methods and the field-effect characteristics. In particular, a benchmark carrier mobility of 20-40 cm 2 Vs −1 , achieved with thin platelets of rubrene single crystals, demonstrates the significance of the SC-OFETs and clarifies material limitations for organic devices. In the latter part of this review, we discuss the physics of microscopic charge transport by using SC-OFETs at metal/semiconductor contacts and along semiconductor/insulator interfaces. Most importantly, Hall effect and electron spin resonance (ESR) measurements reveal that interface charge transport in molecular semiconductors is properly described in terms of band transport and localization by charge traps.

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“…These derivatives exhibit excellent charge transfer properties, the highest charge mobility of which was reported to be 3.6 cm 2 /(V s) [16]. Mas-Torrent et al [17,18] studied dithiophene-tetrathiafulvalene (DT-TTF) and dibenzo-tetrathiafulvalene (DB-TTF), which contain similar molecules but present different crystal packing types, and found that different intermolecular interactions significantly influence the electronic transport properties of the compounds. Naraso et al [19] found that OFET devices based on halogeno-substituted quinoxaline rings fused with TTF show excellent n-type performance and high carrier mobility.…”

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confidence: 99%

Theoretical study of the effects of different substituents of tetrathiafulvalene derivatives on charge transport

2012

Chin. Sci. Bull.

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Density functional theory calculations were carried out to investigate the charge transfer of four tetrathiafulvalene derivatives. Perfluorination of dibenzo-tetrathiafulvalene (DB-TTF) increased the reorganization energy and was considered disadvantageous for the charge-transport process. Fluorination lowered the frontier orbitals of the compound, favoring electron-rather than hole-transport due to the low injection barrier. While intra-ring substitution of carbons of benzene with N atoms did not increase the reorganization energy, it enforced thermodynamic stability and decreased the charge injection barrier due to lowering the frontier orbital. Calculation results also showed that introduction of NH 2 to DB-TTF can change the crystal structure and charge mobility, thus providing a method with which to promote -stacked structures. Calculation of charge transfer integrals using site energy correction methods was found to be more suitable for perfluorinated DB-TTF because it exhibits remarkable polarization effects.theoretical study, substituting effect, charge transport Citation:

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Correlation between Crystal Structure and Mobility in Organic Field-Effect Transistors Based on Single Crystals of Tetrathiafulvalene Derivatives

Cited by 275 publications

References 44 publications

Solution-processed, high-performance n-channel organic microwire transistors

Solution-processed, high-performance n-channel organic microwire transistors

Organic field-effect transistors using single crystals

Theoretical study of the effects of different substituents of tetrathiafulvalene derivatives on charge transport

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