Optically transparent semiconducting polymer nanonetwork for flexible and transparent electronics

Yu, Kilho; Park, Byoungwook; Kim, Geunjin; Kim, Chang‐Hyun; Park, Sung-Jun; Kim, Jehan; Jung, Sungyong; Jeong, Soyeong; Kwon, Sooncheol; Kang, Hongkyu; Kim, Junghwan; Yoon, Myung‐Han; Lee, Kwanghee

doi:10.1073/pnas.1606947113

Cited by 68 publications

(75 citation statements)

References 36 publications

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“…AFM height images ( Fig. 2h) exhibit that the surfaces of both pure and blend film were smooth, while the phase images illustrate that the fiber like morphology which attribute to the aggregation of conjugated-polymer chains was formed in the blend film, similar to the reported results of conjugated-polymer and insulator blends 42,43,49 . Thus, according to UV-vis spectroscopy, GIWAXS and AFM results, the PDPP-…”

Section: Resultssupporting

confidence: 79%

“…By comparison, we find that the 0-0 peak shows a higher intensity value and the peak position shifts to a larger wavelength after blending with PS. This phenomenon has been observed in several conjugatedpolymer and insulator blends, which demonstrates increased aggregation and ordering of conjugated-polymers in the insulator-matrix 42,43,[49][50][51][52][53][54] . The dashed lines in Fig.…”

Section: Resultsmentioning

confidence: 87%

“…A small quantity of conjugated-polymers dispersed in the insulator-matrix could effectively improve the device performance (e.g. mobility and stability) [42][43][44][45][46] , and more importantly, the insulator-matrix could help store charges and enhance the stability of stored charges for long time retention. The stored charges in the insulator-matrix could change the local potential of the channel, which is equivalent to the compensation potential applied to the channel.…”

Section: Resultsmentioning

confidence: 99%

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Reconfigurable Multifunctional Ambipolar Polymer Transistors with Improved Switching-off Capability Upon Non-Uniformly Distributed Compensation Potential

Wei

Wang

et al. 2020

Preprint

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Ambipolar field-effect transistors allowing both holes and electrons transport can work in different states, which are attractive for simplifying the device manufactures and miniaturizing the integrated circuits. However, conventional ambipolar transistors intrinsically suffer from poor switching-off capability because the gate electrode is not able to simultaneously deplete holes and electrons across the entire transport channel. Here, we show that the switching-off capability of polymer ambipolar transistor is largely improved by up to 3 orders, through introducing non-uniformly distributed compensation potentials along the channel to synchronically tune the charge transport at different channel locations. Non-uniformly gate-stressed conjugated-polymer@insulator blend film induces non-uniformly trapped charges in the insulators, which consequently generates non-uniform compensation electrical field imposed in the conjugated-polymers. Both n-type and p-type operations with high mobility (2.2 and 0.8 cm2s-1V-1 respectively) and high on/off ratio (105) are obtained in the same device, and the device states are reversibly switchable, which provides a new strategy for three-level non-volatile memories and artificial synapses.

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Section: Resultssupporting

confidence: 79%

Section: Resultsmentioning

confidence: 87%

Section: Resultsmentioning

confidence: 99%

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Reconfigurable Multifunctional Ambipolar Polymer Transistors with Improved Switching-off Capability Upon Non-Uniformly Distributed Compensation Potential

Wei

Wang

et al. 2020

Preprint

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“…Failing to fully manipulate the distribution of multiple components in a composite-based channel, for instance, may lead to limited reproducibility and large-area uniformity. In addition to the control over the blend solution and annealing, area-selective deposition through anchoring groups and/or the addition of functionally inactive scaffolds can help improve the controllability over phase separation or guide the formation of new nanostructures [ 73 , 82 ].…”

Section: Future Perspectivesmentioning

confidence: 99%

Nanostructured Graphene: An Active Component in Optoelectronic Devices

Kim

2018

Nanomaterials

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Nanostructured and chemically modified graphene-based nanomaterials possess intriguing properties for their incorporation as an active component in a wide spectrum of optoelectronic architectures. From a technological point of view, this aspect brings many new opportunities to the now well-known atomically thin carbon sheet, multiplying its application areas beyond transparent electrodes. This article gives an overview of fundamental concepts, theoretical backgrounds, design principles, technological implications, and recent advances in semiconductor devices that integrate nanostructured graphene materials into their active region. Starting from the unique electronic nature of graphene, a physical understanding of finite-size effects, non-idealities, and functionalizing mechanisms is established. This is followed by the conceptualization of hybridized films, addressing how the insertion of graphene can modulate or improve material properties. Importantly, it provides general guidelines for designing new materials and devices with specific characteristics. Next, a number of notable devices found in the literature are highlighted. It provides practical information on material preparation, device fabrication, and optimization for high-performance optoelectronics with a graphene hybrid channel. Finally, concluding remarks are made with the summary of the current status, scientific issues, and meaningful approaches to realizing next-generation technologies.

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“…There are many possible routes to organic-based neuromorphic architecture, including electrochemical [11,12], memristive [13], and field-effect approaches [14][15][16]. Among them, organic field-effect transistor (OFET)-based synaptic devices are a particularly promising element, considering the possibility of a fully solid-state, flexible neuromorphic chip that leverages the versatility of OFETs in constructing various circuit building blocks [17][18][19][20]. Despite the rapidly growing technological viability of OFET synapses, there is still a lack of understanding on fundamental phenomena prevailing at the single-device level, which acts as a current bottleneck for the development of organic-based complex neuromorphic hardware systems.…”

Section: Introductionmentioning

confidence: 99%

Analysis of the Voltage-Dependent Plasticity in Organic Neuromorphic Devices

Lee¹,

Kim²

2019

Electronics

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The bias-dependent signal transmission of flexible synaptic transistors is investigated. The novel neuromorphic devices are fabricated on a thin and transparent plastic sheet, incorporating a high-performance organic semiconductor, dinaphtho[2,3-b:2′,3′-f]thieno[3,2-b]thiophene, into the active channel. Upon spike emulation at different synaptic voltages, the short-term plasticity feature of the devices is substantially modulated. By adopting an iterative model for the synaptic output currents, key physical parameters associated with the charge carrier dynamics are estimated. The correlative extraction approach is found to yield the close fits to the experimental results, and the systematic evolution of the timing constants is rationalized.

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Optically transparent semiconducting polymer nanonetwork for flexible and transparent electronics

Cited by 68 publications

References 36 publications

Reconfigurable Multifunctional Ambipolar Polymer Transistors with Improved Switching-off Capability Upon Non-Uniformly Distributed Compensation Potential

Reconfigurable Multifunctional Ambipolar Polymer Transistors with Improved Switching-off Capability Upon Non-Uniformly Distributed Compensation Potential

Nanostructured Graphene: An Active Component in Optoelectronic Devices

Analysis of the Voltage-Dependent Plasticity in Organic Neuromorphic Devices

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