Organic Semiconductors for Solution‐Processable Field‐Effect Transistors (OFETs)

Allard, Sybille; Förster, Michael; Souharce, Benjamin; Thiem, Heiko; Scherf, Ullrich

doi:10.1002/anie.200701920

Cited by 1,113 publications

(729 citation statements)

References 208 publications

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“…[1][2][3] Although electron mobility remains a challenge, these represent lightweight, flexible alternatives that are more readily processed using solution-based methods. Within this arena, the opportunities proffered by the exceptional electronic and physical properties of graphene and its derivatives are undeniable.…”

mentioning

confidence: 99%

Methoxy functionalisation: exerting synthetic control of the supramolecular and electronic structure of nitrogen-doped nanographenes

et al. 2014

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We describe a series of functionalized N-containing heterosuperbenzenes, created with a view to investigating the strategic role of methoxy substituents in (i) promoting cyclodehydrogenation and (ii) tuning the electronic properties and (iii) the supramolecular order in the resultant fused products.The dominance of inorganic semiconductors in the manufacture of optoelectronic devices and field effect transistors is gradually being undermined by the emergence of functional organic materials. [1][2][3] Although electron mobility remains a challenge, these represent lightweight, flexible alternatives that are more readily processed using solution-based methods. Within this arena, the opportunities proffered by the exceptional electronic and physical properties of graphene and its derivatives are undeniable. [4][5][6] As many aspects in the formation of large graphitic sheets are difficult to control, synthetic chemists have pioneered routes to nanographenes with impressive and varying dimensions, and an array of peripheral substituents. 7-10 Dependent on the latter are a range of material characteristics e.g. the nature of the p-p interactions, HOMO-LUMO gaps and film-forming capabilities. [11][12][13][14] The ability to manufacture graphene systems to such specificity is notably absent in exfoliation 15 /epitaxial growth 16 processes, and this makes the further development of bottom-up synthetic methodologies for the formation of next-generation and heteroatomcontaining graphenes all the more important. 10,17 Oxidative cyclodehydrogenation is a key step in the chemical formation of planarised ring systems. All-carbon systems cyclise rapidly, while heteroatom-containing polyphenylenes appear to adopt a more complex mechanism for ring closure, e.g. both partially and fully fused species tend to be generated in a single reaction. [18][19][20] Electron donating substituents both direct and promote CC bond formation under cyclodehydrogenation conditions. 21,22 Tuning the intramolecular properties of graphenes is one step in the search for technology-enabling materials. Also essential is the ability to exert some supramolecular control of structure. Disc-like molecules tend to aggregate in columnar p-p stacks which can be either enhanced or perturbed by peripheral units e.g. long chain alkyl substituted hexaperihexabenzocoronenes frequently exhibit liquid crystalline behaviour, 2 whereas their iodo-or tert-butyl-functionalised derivatives give rise to Bernal-stacked crystalline dimers. 23 This work reveals how the combination of heteroatom doping (as pioneered by Draper et al.), 17,24-26 with H-bonding peripheral substituents, can unlock some exciting new applications for nanographene materials by controlling the outcome of the synthetic process and the HOMO-LUMO gaps and intermolecular order of the end-products.The synthetic methods used to form the precursor polyphenylenes were modifications of published routes involving cyclopentadienones (generated via two-fold Knoevenagel condensations) and their subsequent [2+4] D...

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Methoxy functionalisation: exerting synthetic control of the supramolecular and electronic structure of nitrogen-doped nanographenes

et al. 2014

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“…Polymers and low-molar-mass materials containing electro-active moieties and capable of thin amorphous film formation are known for various applications such as active layers in organic light emitting diodes (OLEDs), [1][2][3][4][5][6] photovoltaic cells, [7][8][9][10] field effect transistors [11,12] and photorefractive materials. [13,14] Amorphous electro-active layers of polymers can be fabricated using simple techniques.…”

Section: Introductionmentioning

confidence: 99%

Polyethers containing 3,6-diarylcarbazolyl groups as polymeric materials for hole transporting layers of OLEDs

Kručaitė

Liu

Volyniuk

et al. 2015

Designed Monomers and Polymers

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Several polyethers containing pendent 3,6-diarylcarbazolyl moieties have been synthesized by the multi-step synthetic routes. Full characterization of their structures is presented. The polymers represent materials of high thermal stability with initial thermal degradation temperatures exceeding 419°C. The glass transition temperatures of the amorphous materials were in the range of 66-108°C. The electron photoemission spectra of thin layers of the polymers showed ionization potentials in the range of 5.47-5.69 eV. Hole transporting properties of the polymeric materials were tested in the structures of organic light emitting diodes with Alq 3 as the green emitter. The device containing hole transporting layers of the polymer with 3,6-di(4-biphenyl)carbazolyl moieties exhibited the best overall performance with a maximum photometric efficiency of about 2.3 cd/A and maximum brightness exceeding 2630 cd/m 2 .

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“…The problem, however, is that most of small molecular organic semiconductors with high performance are not soluble in common solvent due to their highly conjugated molecular structures and cannot be handled by wet-processes. For that reason, people have tried to use polymers as the active materials utilizing their high solubility [14,15], or to use precursor molecules for the formation of the active film [16][17][18][19], or to synthesis new soluble materials [20][21][22][23][24]. There seems, however, to be performance limits or serious demerits in those approaches although the performance of wet-processed OTFTs has been improved rapidly so far.…”

Section: Introductionmentioning

confidence: 99%

“…Substitution of solubilizing groups on highly conjugated backbone is usually accompanied by unintended and unfavorable change in molecular-packing pattern by distorting the molecular backbone or by steric hindrance of huge substituents, which results in limited device performance [20][21][22][23][24][28][29][30][31]. Therefore, it is highly desirable to make OTFTs with small molecular organic semiconductors without any molecular modification nor performance decrease using some simple wet-processes.…”

Section: Introductionmentioning

confidence: 99%

Wet-processed n-type OTFTs utilizing highly-stable colloids of a perylene diimide derivative

Jeon

Oguma

Hirata

et al. 2013

Organic Electronics

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Organic Semiconductors for Solution‐Processable Field‐Effect Transistors (OFETs)

Cited by 1,113 publications

References 208 publications

Methoxy functionalisation: exerting synthetic control of the supramolecular and electronic structure of nitrogen-doped nanographenes

Methoxy functionalisation: exerting synthetic control of the supramolecular and electronic structure of nitrogen-doped nanographenes

Polyethers containing 3,6-diarylcarbazolyl groups as polymeric materials for hole transporting layers of OLEDs

Wet-processed n-type OTFTs utilizing highly-stable colloids of a perylene diimide derivative

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