Self-Assembly, Molecular Packing, and Electron Transport in n-Type Polymer Semiconductor Nanobelts

Briseño, Alejandro L.; Mannsfeld, Stefan C. B.; Shamberger, Patrick J.; Ohuchi, Fumio S.; Bao, Zhenan; Jenekhe, Samson A.; Xia, Younan

doi:10.1021/cm8010265

Cited by 161 publications

(148 citation statements)

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

Oh¹,

Lee²,

Mannsfeld³

et al. 2009

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

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222

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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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confidence: 99%

mentioning

confidence: 99%

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

Oh¹,

Lee²,

Mannsfeld³

et al. 2009

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

Self Cite

222

197

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“…We conclude that the crystals of form D grew along the a axis, which coincides with the π-π stacking direction. [23,24] Adv. Electron.…”

Section: Introductionmentioning

confidence: 99%

Tuning Luminescence and Conductivity through Controlled Growth of Polymorphous Molecular Crystals

Chen

Liu

et al. 2017

Adv Elect Materials

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on the basis of traditional conductive polymers. Over the last couple of decades, however, much progress has been made in the development of optoelectronic devices based on organic small molecules. [8,12] Several archetypical polymorphic mole cular solids are of high interest and utility in optical and electronic applications. [8][9][10][11][12] Previous studies of archetypical polymor phic systems have found that the crystal lization of polymorphs can be affected by many factors, principally the nature of the solvent and the presence of additives. [13,14] These materials have provided great opportunities to explore the fundamentals of polymorphism. [15] Indeed, determining the origins of polymorphism is important for both applied science and our funda mental understanding of crystal packing and structure-property relationships.For organic semiconductors, charge transport between organic molecules is related to the degree of electronic coupling among neighboring molecules as well as the reorganization energy involved during transformations from neutral to charged or charged to neutral states. [16,17] Nevertheless, clear structure-property correlations can be difficult to identify, especially for the same compound in different molecular crystal packing arrangements which can influence the resulting optical and electronic properties. In this study, we have found that different packing styles can lead to single crystals exhibiting dramatically different optical and elec tronic properties. Herein, we describe the synthesis and struc tural characterization of a polymorphic compound (E)2{4[4 (9Hcarbazol9yl)styryl]benzylidene}malononitrile (TCBR) and reveal how its luminescence and electronic properties depend on its modes of packing in the solid state. In particular, we have found that crystals featuring different stacking modes exhibit distinctly different charge transport characteristics. Results and DiscussionThe synthesis of the molecule TCBR is illustrated in Scheme 1. The novel acetalprotected stilbene 1, selected for extension of the π conjugation, was prepared through a Wadsworth-Emmons reaction. Starting from the diethyl phosphonate, the trans stilbene form of 1 was obtained preferentially. Subsequent removal of the acetal group, using trifluoroacetic acid, afforded the desired (E)4[4(9Hcarbazol9yl)styryl]benzaldehyde 2.Clear structure-property correlation is of crucial importance for molecular materials for optical and electronic application. Here, a new intramolecular charge transfer compound (E)-2-{4-[4-(9H-carbazol-9-yl)styryl]benzylidene}-malononitrile (TCBR) with a dicyanovinyl group as the electron acceptor and a carbazole group as the electron donor is designed and synthesized. Four different single crystals based on the cis and trans isomeric forms of this compound are grown simultaneously, which are both kinetically and thermodynamically stable. The different packing modes give rise to a dynamic crystal structure change, leading to dramatically different optical and electronic properties. The closer...

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“…Depending on the material, and growth conditions, some variations on the NW morphology have also been observed, e.g. flat 'nanobelts' [12] or curved 'nanofibres' [13]. We will here refer to all of these related morphologies as 'nanowires' as generic term, except when discussing a specific sample.…”

Section: Introductionmentioning

confidence: 99%

“…As n type organic semiconductor, we have selected poly(benzimidazobenzophenanthroline) (BBL). BBL can act as n type material in organic TFTs with good mobility ( e = 0.1 cm 2 /Vs) [20], and Briseno et al [12] have reported on the growth of BBL 'nanobelts'. BBL possesses a rather deep 'lowest unoccupied molecular orbital' (LUMO) of 4.0 eV [21], which allows reasonable electron injection even from high work function metals, and may make BBL consistent with water gating, despite the potential trapping of electrons by water and/or oxygen: Nicolai et al [22] recently suggested from theoretical calculations that such trapping can be avoided when the LUMO is more than 3.6 eV below vacuum level.…”

Section: Introductionmentioning

confidence: 99%