Effect of Nonconjugated Spacers on Mechanical Properties of Semiconducting Polymers for Stretchable Transistors

Mun, Je Ho; Wang, Ging‐Ji Nathan; Oh, Jin Young; Katsumata, Tōru; Lee, Franklin L.; Kang, Jiheong; Wu, Hung‐Chin; Lissel, Franziska; Rondeau‐Gagné, Simon; Tok, Jeffrey B.‐H.; Bao, Zhenan

doi:10.1002/adfm.201804222

Cited by 143 publications

(170 citation statements)

References 60 publications

(102 reference statements)

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“…Recently, D‐A CPs with non‐conjugated spacers in the backbone have received considerable interest, owing to fact that these flexible spacers yield great improvement in the deformability while good charge transport mobility is not detrimentally affected . Meanwhile, as suggested by molecular dynamics simulation, the dynamics of polymer chains can be enhanced by the nonconjugated flexible spacers . On the contrary, with the insertion of a conjugated spacer like thiophene unit into the polymer backbone while maintaining the same sidechain length, PA4T‐BC2‐C10C12 shows a 25 °C increase in T g than that of PA3T‐BC2‐C10C12 (chemical structures shown in Table ).…”

Section: Glass Transition For Conjugated Polymersmentioning

confidence: 99%

Glass Transition Phenomenon for Conjugated Polymers

Qian

Cao

Galuska

et al. 2019

Macro Chemistry & Physics

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Conjugated polymers are emerging as promising building blocks for a broad range of modern applications including skin‐like electronics, wearable optoelectronics, and sensory technologies. In the past three decades, the optical and electronic properties of conjugated polymers have been extensively studied, while their thermomechanical properties, especially the glass transition phenomenon which fundamentally represents the polymer chain dynamics, have received much less attention. Currently, there is a lack of design rules that underpin the glass transition temperature of these semirigid conjugated polymers, putting a constraint on the rational polymer design for flexible stretchable devices and stable polymer glass that is needed for the devices’ long‐term morphology stability. In this review article, the glass transition phenomenon for polymers, glass transition theories, and characterization techniques are first discussed. Then previous studies on the glass transition phenomenon of conjugated polymers are reviewed and a few empirical design rules are proposed to fine‐tune the glass transition temperature for conjugated polymers. The review paper is finished with perspectives on future directions on studying the glass transition phenomena of conjugated polymers. The goal of this perspective is to draw attention to challenges and opportunities of controlling, predicting, and designing polymeric semiconductors, specifically to accommodate their end use.

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Section: Glass Transition For Conjugated Polymersmentioning

confidence: 99%

Glass Transition Phenomenon for Conjugated Polymers

Qian

Cao

Galuska

et al. 2019

Macro Chemistry & Physics

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“…Several strategies have been used to overcome this tradeoff. For example, researchers have reported the usage of chemically bound rubbery blocks, [ 30,31 ] soft crosslinkers, [ 32 ] energy dissipating moieties, [ 23 ] host elastomeric matrices, [ 25,27,33–35 ] nanoconfined semiconducting polymers, [ 7,22,36 ] conjugation breakers, [ 37–39 ] and molecular additives. [ 40 ] Such strategies have resulted in improved stretchability of semiconducting polymers, along with small decrease in mobility.…”

Section: Introductionmentioning

confidence: 99%

F4‐TCNQ as an Additive to Impart Stretchable Semiconductors with High Mobility and Stability

Mun

Kang

Zheng

et al. 2020

Adv Elect Materials

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Numerous strategies are developed to impart stretchability to polymer semiconductors. Although these methods improve the ductility, mobility, and stability of such stretchable semiconductors, they nonetheless still need further improvement. Here, it is shown that 2,3,5,6‐tetrafluoro‐7,7,8,8‐tetracyanoquinodimethane (F4‐TCNQ) is an effective molecular additive to tune the properties of a diketopyrrolopyrrole‐based (DPP‐based) semiconductor. Specifically, the addition of F4‐TCNQ is observed to improve the ductility of the semiconductor by altering the polymer’s microstructures and dynamic motions. As a p‐type dopant additive, F4‐TCNQ can also effectively enhance the mobility and stability of the semiconductor through changing the host polymer’s packing structures and charge trap passivation. Upon fabricating fully stretchable transistors with F4‐TCNQ‐DPP blended semiconductor films, it is observed that the resulting stretchable transistors possess one of the highest initial mobility of 1.03 cm2 V−1 s−1. The fabricated transistors also exhibit higher stability (both bias and environmental) and mobility retention under repeated strain, compared to those without F4‐TCNQ additive. These findings offer a new direction of research on stretchable semiconductors to facilitate future practical applications.

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“…The stretchability of such polymers could be enhanced by modifying the chemical structure of the mono mer, including their backbone and side-chains, which greatly affect the chain dynamics and the internal morphology of the polymer. [208][209][210][211][212] Recently, Oh et al [116] introduced series of semiconducting co-polymers to manipulate the material properties of semiconducting polymers, also known as molecular structure engineering (Figure 5a). By inserting nonconjugated 2,6-pyridinedicarboxamide (PDCA) segments into the repeating segments of DPP-based original polymers, conjugation inside the polymeric network was disrupted and hydrogen bonds were newly formed between the adjacent polymer chains (P1 to P4).…”

Section: Modifying the Molecular Chemical Structurementioning

confidence: 99%

Material‐Based Approaches for the Fabrication of Stretchable Electronics

et al. 2019

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exhibits high potential for a wide range of bio-electronics applications that need to be mechanically deformable, such as personalized healthcare systems, [4,5] wearable smart displays, [6][7][8] and implantable prosthetic devices, [9][10][11] while rigid electronics suffer in fully exhibiting their original performance on such applications.The evolution of stretchable electronics was initially driven by advancements in human bio-signal sensing technologies. A variety of stretchable sensors, such as thermal sensors (e.g., temperature, thermal conductivity), [12][13][14] mechanical sensors (e.g., strain, pressure), [15][16][17] optical sensors (e.g., pulse oximetry, photoplethysmogram (PPG)), [6,18,19] electrophysiology (EP) sensors (e.g., electroencephalogram (EEG), electrocardiogram (ECG)), [20][21][22] and biochemical sensors (e.g., glucose, pH), [23][24][25][26] have been developed aided by unconventional electronic materials and device designs. As these stretchable sensors tend to mimic the unique mechanical properties of soft and deformable human tissues, stable conformal contact between these sensors and human skin and/or internal organs is achievable. This unique biotic/abiotic interfacing results in outstanding sensing accuracies and extraordinary signal-to-noise ratios that surpass the performance of rigid bio-sensing devices.As stretchable sensor technology has evolved, there has been a growing demand for other stretchable electronic components capable of processing signals retrieved from stretchable sensors. The stretchable electronics research direction has therefore moved toward building stretchable integrated electronic systems that consist not only of stretchable sensory components, but also of other advanced stretchable electronic components for signal processing, feedback actuation, real-time display, wireless communication, and power supply. [27,28] Considerable research effort has been devoted by material scientists and device engineers to achieving fully integrated stretchable electronic systems.The research approaches to such stretchable sensors, additional electronic components, and fully integrated systems are largely categorized by two strategies, namely the "structurebased" and "material-based" approaches. For the structurebased approach, technologies for conventional electronics are utilized to build stretchable electronic systems in which the superb performance of conventional electronics can be fully Stretchable electronics are mechanically compatible with a variety of objects, especially with the soft curvilinear contours of the human body, enabling human-friendly electronics applications that could not be achieved with conventional rigid electronics. Therefore, extensive research effort has been devoted to the development of stretchable electronics, from research on materials and unit device, to fully integrated systems. In particular, material-processing technologies that encompass the synthesis, assembly, and patterning of intrinsically stretchable electronic materials have been ac...

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Effect of Nonconjugated Spacers on Mechanical Properties of Semiconducting Polymers for Stretchable Transistors

Cited by 143 publications

References 60 publications

Glass Transition Phenomenon for Conjugated Polymers

Glass Transition Phenomenon for Conjugated Polymers

F4‐TCNQ as an Additive to Impart Stretchable Semiconductors with High Mobility and Stability

Material‐Based Approaches for the Fabrication of Stretchable Electronics

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