Vertical Phase Separation in Small Molecule:Polymer Blend Organic Thin Film Transistors Can Be Dynamically Controlled

Wodo, Olga; Ren, Dingding; Khan, Hadayat Ullah; Niazi, Muhammad Rizwan; Hu, Hanlin; Abdelsamie, Maged; Li, Ruipeng; Li, Er. Qiang; Yu, Liyang; Yan, Bicheng; Payne, Marcia M.; Smith, Jeremy; Anthony, John E.; Anthopoulos, Thomas D.; Thoroddsen, Sigurður T.; Ganapathysubramanian, Baskar; Amassian, Aram

doi:10.1002/adfm.201503943

Cited by 104 publications

(108 citation statements)

References 43 publications

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“…On the other hand, the PS, PαMS, and PTAA blends often form trilayer structure a polymer layer sandwiched between top and bottom small molecule OSC layers. [209] As a result of many efforts expended on this blend approach, diF-TES-ADT FETs with charge-carrier mobility values greater than 5 cm 2 V −1 s −1 have recently been reported, which is comparable to the result for a single-crystal device using the same material. Shin and coworker demonstrated the migration of diF-TES-ADT molecules toward the polar substrate to be driven by entropy rather than enthalpy.…”

Section: Wileyonlinelibrarycommentioning

confidence: 63%

Effective Use of Electrically Insulating Units in Organic Semiconductor Thin Films for High‐Performance Organic Transistors

Kang

Qiu

et al. 2016

Adv Elect Materials

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The electrical properties of organic semiconductors (OSCs), whether they are conjugated small molecules or polymers, can be tailored by incorporating electrically insulating units (EIUs), which are organic moieties consisting of nonconjugated units. EIUs can be introduced to a thin film by synthetically connecting them to the otherwise conjugated OSC molecules or by blending them in as separate EIU molecules with the OSCs during the thin‐film fabrication process. The engineered EIUs are capable of imparting various additional functions to the OSC thin film and improving their electrical properties. In this review article, a comprehensive overview of various effects of EIUs on OSC thin films and their consequent electrical performance when used as active layers in organic field‐effect transistors (OFETs) is provided. A broad range of studies of the synthetic approaches of incorporating EIUs, such as those using side chains, block copolymers, and conjugation‐break spacers, and of the blending approaches with organic insulators is discussed. Finally, a brief summary and perspectives for future research in this field are presented.

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Section: Wileyonlinelibrarycommentioning

confidence: 63%

Effective Use of Electrically Insulating Units in Organic Semiconductor Thin Films for High‐Performance Organic Transistors

Kang

Qiu

et al. 2016

Adv Elect Materials

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“…We further tested our hypothesis by inserting an ultrathin layer (∼10 nm) of polystyrene between the organic semiconductor film and the SiO 2 dielectric by blending the semiconductor with polystyrene, which can spontaneously stratify into bilayer structures during solution processing with the polystyrene layer buried between the semiconductor and SiO 2 (46,60,61). The polystyrene layer has a CTE of 72 ppm/K (62), which is very similar to the CTE of the organic semiconductor incorporated in these devices (diF-TES ADT, CTE =162 ppm/K), yielding an ITEM of 2.3.…”

Section: Mechanism Of Trap Formation Due To Thermal Strain: Modeling Andmentioning

confidence: 99%

Crossover from band-like to thermally activated charge transport in organic transistors due to strain-induced traps

Mei

Diemer

Niazi

et al. 2017

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

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“…By tuning these relevant parameters, many possible morphologies can be made from the phase separation. Various phase‐separated morphologies have been applied in organic electronics, such as OFETs, OLEDs, organic photovoltaic solar cells (OPVs), etc., to improve device performance . Motivated by the previous research in phase‐separated microstructures, we are interested in developing isolated charge trapping sites using WBG organic semiconductor materials by phase separation from spin‐coating blend solutions.…”

mentioning

confidence: 99%

Solution‐Processed Wide‐Bandgap Organic Semiconductor Nanostructures Arrays for Nonvolatile Organic Field‐Effect Transistor Memory

Wen

Guo

Ling

et al. 2017

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In this paper, the development of organic field-effect transistor (OFET) memory device based on isolated and ordered nanostructures (NSs) arrays of wide-bandgap (WBG) small-molecule organic semiconductor material [2-(9-(4-(octyloxy)phenyl)-9H-fluoren-2-yl)thiophene]3 (WG ) is reported. The WG NSs are prepared from phase separation by spin-coating blend solutions of WG /trimethylolpropane (TMP), and then introduced as charge storage elements for nonvolatile OFET memory devices. Compared to the OFET memory device with smooth WG film, the device based on WG NSs arrays exhibits significant improvements in memory performance including larger memory window (≈45 V), faster switching speed (≈1 s), stable retention capability (>10 s), and reliable switching properties. A quantitative study of the WG NSs morphology reveals that enhanced memory performance is attributed to the improved charge trapping/charge-exciton annihilation efficiency induced by increased contact area between the WG NSs and pentacene layer. This versatile solution-processing approach to preparing WG NSs arrays as charge trapping sites allows for fabrication of high-performance nonvolatile OFET memory devices, which could be applicable to a wide range of WBG organic semiconductor materials.

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Vertical Phase Separation in Small Molecule:Polymer Blend Organic Thin Film Transistors Can Be Dynamically Controlled

Cited by 104 publications

References 43 publications

Effective Use of Electrically Insulating Units in Organic Semiconductor Thin Films for High‐Performance Organic Transistors

Effective Use of Electrically Insulating Units in Organic Semiconductor Thin Films for High‐Performance Organic Transistors

Crossover from band-like to thermally activated charge transport in organic transistors due to strain-induced traps

Solution‐Processed Wide‐Bandgap Organic Semiconductor Nanostructures Arrays for Nonvolatile Organic Field‐Effect Transistor Memory

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