Tuning Interfacial Properties by Spontaneously Generated Organic Interlayers in Top‐Contact‐Structured Organic Transistors

Choi, Giheon; Oh, Seong Hoon; Seo, Jungyoon; Lee, Hwa Sung

doi:10.1002/adfm.202002979

Cited by 12 publications

(10 citation statements)

References 61 publications

(56 reference statements)

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“…Because the P3HT/ZIF-8 hybrid thin films exhibited identical UV–vis absorption spectra (Figure S1), the increased hole mobility and OTFT performance are attributed to the electrical conductivity of the carbonized ZIF-8s rather than to structural development of P3HT crystals or charge-transfer doping of P3HT chains from carbonized ZIF-8s (Figure ). , The carbonized ZIF-8 clusters are conductive, , which can reduce the effective channel length between the source and drain electrodes (i.e., the charge bridge effect) . The reduced channel length can increase the nominal hole mobility evaluated from the transfer curves.…”

Section: Results and Discussionmentioning

confidence: 99%

Metal–Organic Framework as a Functional Analyte Channel of Organic-Transistor-Based Air Pollution Sensors

Lee

Kim

Park

et al. 2021

ACS Appl. Mater. Interfaces

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Air pollution sensors based on organic transistors have attracted much interest recently; however, the devices suffer from low responsivity and slow response and recovery rates for gas analytes. These shortcomings are attributed to the low charge-carrier mobility of organic semiconductors and to a structural limitation resulting from the use of a thick and continuous active layer. In the present work, we investigated the material properties of a multiscale porous zeolitic imidazolate framework, [Zn(2-methylimidazole)2] n (ZIF-8), and examined its potential as an analyte channel material inserted at an organic-transistor active layer. A series of carbonized zeolitic imidazolate frameworks (ZIFs) were prepared by thermal conversion of ZIF-8 and also studied for comparison. The microstructures, morphologies, and optical/electrical characteristics of polythiophene/ZIF-8 hybrid films were systematically investigated. Organic-transistor-type nitrogen dioxide sensors based on the polythiophene/ZIF-8 hybrid films showed substantially improved sensing properties, including responsivity, response rate, and recovery rate. The electrical conductivity of the carbonized ZIF-8s enhanced the field-effect mobility of the organic transistors; however, the sensing performance was not improved, because of the closed pore structures resulting from the carbonization. These results provide invaluable information and useful insights into the design of transistor-type gas sensors based on organic semiconductor/metal–organic framework hybrid films.

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Section: Results and Discussionmentioning

confidence: 99%

Metal–Organic Framework as a Functional Analyte Channel of Organic-Transistor-Based Air Pollution Sensors

Lee

Kim

Park

et al. 2021

ACS Appl. Mater. Interfaces

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“…[ 22–25 ] Several methods have been proposed to reduce the contact resistance and improve charge injection at metal/organic interface, such as contact doping, introducing a charge injection layer, or forming an abrupt damage‐free metal/semiconductor interface by transferred electrodes. [ 2,5,24–30 ] However, these methods require additional and complicated processes, which increase the difficulty of device fabrication and some of them also damage organic films. [ 27 ] Actually, due to the dynamic impact of metal deposition process, the disordered metal/organic interface may be a thermodynamically non‐equilibrium state, which could be potentially reformed to construct a more ordered and stable structure spontaneously, thereby eliminating the adverse effects of metal deposition.…”

Section: Introductionmentioning

confidence: 99%

“…[22][23][24][25] Several methods have been proposed to reduce the contact resistance and improve charge injection at metal/organic interface, such as contact doping, introducing a charge injection layer, or forming an abrupt damage-free metal/semiconductor interface by transferred electrodes. [2,5,[24][25][26][27][28][29][30] However, these methods require additional and complicated processes, which increase the difficulty of device fabrication and some of them also…”

Section: Introductionmentioning

confidence: 99%

Improving Charge Injection at Gold/Conjugated Polymer Contacts by Polymer Insulator‐Assisted Annealing for Transistors

Wei

Shen

Qin

et al. 2021

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The poor chemical miscibility between metal and organic materials usually leads to both structural and energetic mismatches at gold/organic interfaces, and thereby, high contact resistance of organic electronic devices. This study shows that the contact resistance of organic field‐effect transistors is significantly reduced by one order of magnitude, by reforming the contact interface between gold electrodes and conjugated polymers upon a polymer insulator‐assisted thermal annealing. Upon an optimized solution process, the conjugated polymer is homogenously distributed within the amorphous polymer insulator matrix with relatively low glass transition temperature, and thus, even a moderate annealing temperature can induce sufficient motion of conjugated polymer chains to simultaneously adjust the polymer orientation and improve the packing of gold atoms. Consequently, gold/conjugated polymer contact is reorganized after annealing, which improves both charge transport from bulk gold to interface and charge injection from gold into conjugated polymers. This method, with appropriate insulator matrix, is effective for improving the injection of both holes and electrons, and widely applicable for many unipolar and ambipolar conjugated polymers to optimize the device performance and simultaneously increase the optical transparency (over 80%). A frequency doubler and a phase modulator are demonstrated, respectively, using the ambipolar transistors with optimized charge injection properties.

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“…Organic active materials are gaining extensive attention in various fields of flexible wearable electronic devices, [1][2][3] including radio-frequency identification tags, [4,5] flexible displays, [6,7] and physical/chemical sensors owing to their advantages such as mechanical flexibility, [8][9][10] easy molecular design, [11][12][13] and solution processing. [14][15][16] Among various application fields, organic physical and chemical sensors are core elements of wearable devices for collecting information of biomechanical and physiological data to diagnose a human disease or monitoring exercise status. A representative indicator for monitoring health status is L-lactic acid (LA) concentration in blood or sweat.…”

Section: Introductionmentioning

confidence: 99%

Exploration on Solvatochromic Sensing Probe of Phenol Blue for L‐Lactic Acid Detection: Effective Strategy to Obtain Reliable Capacitive Sensor

Seo

Hwang

et al. 2022

Adv Funct Materials

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This study systematically investigates a capacitive sensor applied with phenol blue (PhB)-based sensing medium for detection of L-lactic acid (LA), as a health monitoring indicator. PhB is a substance with solvatochromic effect, inducing the change in capacitance by exposure to polar molecules. However, the capacitive LA sensor with a flat-structured PhB/polyvinylchloride (PVC) composite-sensing medium is observed to have a problem in that sensing capacitance variation saturate quickly with increasing the LA solution concentration. This main cause can be analyzed that the interaction of proton from LA molecule with the lone pair electrons of the PhB molecule acts as a major factor on the sensing characteristics rather than the solvatochromic behavior of PhB molecule. Therefore, a strategy is adopted to introduce a porous structure to the PhB/PVC composite-sensing medium to maximize the interaction of PhB with protons, which is implemented through solvent and non-solvent exchange methods. Consequently, the sensitivity and linearity of the porous-structured LA sensor are 2.99 pF mm −1 and 0.966 over LA concentrations ranging from 0 to 100 mm, respectively, which is a significant improvement over that of the flat-structured one. Notably, the sensing performance remained unchanged even after a month of storage under normal ambient conditions.

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Tuning Interfacial Properties by Spontaneously Generated Organic Interlayers in Top‐Contact‐Structured Organic Transistors

Cited by 12 publications

References 61 publications

Metal–Organic Framework as a Functional Analyte Channel of Organic-Transistor-Based Air Pollution Sensors

Metal–Organic Framework as a Functional Analyte Channel of Organic-Transistor-Based Air Pollution Sensors

Improving Charge Injection at Gold/Conjugated Polymer Contacts by Polymer Insulator‐Assisted Annealing for Transistors

Exploration on Solvatochromic Sensing Probe of Phenol Blue for L‐Lactic Acid Detection: Effective Strategy to Obtain Reliable Capacitive Sensor

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