Tuning the Mechanical Properties of a Polymer Semiconductor by Modulating Hydrogen Bonding Interactions

Zheng, Yu; Ashizawa, Minoru; Song, Zhanqian; Kang, Jiheong; Nikzad, Shayla; Yu, Zhiao; Ochiai, Yuto; Wu, Hung‐Chin; Tran, Helen; Mun, Je Ho; Tok, Jeffrey B.‐H.; Gu, Xiaodan; Bao, Zhenan

doi:10.1021/acs.chemmater.0c01437

Cited by 92 publications

(118 citation statements)

References 60 publications

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“…In stretchable electronics applications, our terpolymer semiconductors may be used under strain, which requires understanding the microstructure change in the stretched terpolymer semiconductor films. Several mechanisms can result in dissipating applied mechanical stress, such as chain stretching and alignment in amorphous domains, breaking aggregates and/or crystalline domains, rotation of monomer units, and breaking weaker bonding (i.e., hydrogen bonding or metal-ligand bonding) 32,34,[46][47][48] . We hypothesized that our terpolymers with low degree of crystallinity and lack of large crystalline domains may effectively dissipate applied mechanical stress without affecting their crystalline domains.…”

Section: Improved Mechanical Properties Without Compromise In Mobilitymentioning

confidence: 99%

“…For example, charge carrier mobility is often reduced with increasing stretchability, which significantly limits the use of stretchable semiconducting polymers 30,31 . Even though significant progress has been made with the incorporation of dynamic bonding units, partial breakage of the conjugation makes it challenging to control the morphology, which makes it difficult to realize high mobility [32][33][34] . Several types of additives have been reported and have shown some promise.…”

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confidence: 99%

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A design strategy for high mobility stretchable polymer semiconductors

et al. 2021

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As a key component in stretchable electronics, semiconducting polymers have been widely studied. However, it remains challenging to achieve stretchable semiconducting polymers with high mobility and mechanical reversibility against repeated mechanical stress. Here, we report a simple and universal strategy to realize intrinsically stretchable semiconducting polymers with controlled multi-scale ordering to address this challenge. Specifically, incorporating two types of randomly distributed co-monomer units reduces overall crystallinity and longer-range orders while maintaining short-range ordered aggregates. The resulting polymers maintain high mobility while having much improved stretchability and mechanical reversibility compared with the regular polymer structure with only one type of co-monomer units. Interestingly, the crystalline microstructures are mostly retained even under strain, which may contribute to the improved robustness of our stretchable semiconductors. The proposed molecular design concept is observed to improve the mechanical properties of various p- and n-type conjugated polymers, thus showing the general applicability of our approach. Finally, fully stretchable transistors fabricated with our newly designed stretchable semiconductors exhibit the highest and most stable mobility retention capability under repeated strains of 1,000 cycles. Our general molecular engineering strategy offers a rapid way to develop high mobility stretchable semiconducting polymers.

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Section: Improved Mechanical Properties Without Compromise In Mobilitymentioning

confidence: 99%

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confidence: 99%

A design strategy for high mobility stretchable polymer semiconductors

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“…Finally, these materials responded to bodily movements such as twisting and bending of joints that they were appended to. In a more recent study, Zheng et al assessed the correlation between strength of hydrogen bonding through conjugation breakers and polymer physical properties 106 . Stronger hydrogen bonding through urea groups yielded materials with higher flexibility, modulus, and charge mobility.…”

Section: Hydrogen Bondingmentioning

confidence: 99%

Optimizing the self‐assembly of conjugated polymers and small molecules through structurally programmed non‐covalent control

Mullin

Sharber

Thomas

2021

Journal of Polymer Science

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Organic conjugated polymers and oligomers are key electronic materials for applications such as transistors, photovoltaics, and light emitting devices due to their potential for solution processability, mechanical flexibility, and precise structure-based tuning compared to inorganic materials. In dilute environments, the optoelectronic properties of conjugated polymers are largely governed by their constitutional structure and, to a lesser degree, their solution-state intramolecular configuration. In the solid state, intramolecular conformation and intermolecular electronic coupling impact these properties substantially, especially in relation to device performance. Therefore, an increasingly important area of research concerning conjugated materials is developing design strategies aimed at optimizing the solid-state packing for electronic applications. Programming solid-state packing arrangements through discrete non-covalent interactions is an emerging strategy within the context of conjugated polymers. This review focuses on the use of the two most prevalent discrete and directional interactions used to dictate the self-assembly of conjugated polymers and oligomers-hydrogen bonds and chalcogen bonds. We also discuss how these design motifs can imbue conjugated materials with appealing physical properties while simultaneously retaining or improving electronic capabilities.

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“…[ 21–25 ] The strength of the dynamic bonds as well as number and position of the mechanophoric units were shown to be crucial factors for modulating the resulting mechanical properties. Recently, mechanophores based on hydrogen bonds have been employed in the backbone [ 26–28 ] or side chain [ 29 ] of PSCs as dynamic crosslinkers to facilitate thin film deformability. However, mechanophores usually break the conjugation of the polymer backbone, thereby reducing the charge carrier mobility.…”

Section: Introductionmentioning

confidence: 99%

Metal–Ligand Based Mechanophores Enhance Both Mechanical Robustness and Electronic Performance of Polymer Semiconductors

Lissel

Wang

et al. 2021

Adv Funct Materials

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The backbone of diketopyrrolopyrrole‐thiophene‐vinylene‐thiophene‐based polymer semiconductors (PSCs) is modified with pyridine (Py) or bipyridine ligands to complex Fe(II) metal centers, allowing the metal–ligand complexes to act as mechanophores and dynamically crosslink the polymer chains. Mono‐ and bi‐dentate ligands are observed to exhibit different degrees of bond strengths, which subsequently affect the mechanical properties of these Wolf‐type‐II metallopolymers. The counter ion also plays a crucial role, as it is observed that Py‐Fe mechanophores with non‐coordinating BPh4– counter ions (Py‐FeB) exhibit better thin film ductility with lower elastic modulus, as compared to the coordinating chloro ligands (Py‐FeC). Interestingly, besides mechanical robustness, the electrical charge carrier mobility can also be enhanced concurrently when incorporating Py‐FeB mechanophores in PSCs. This is a unique observation among stretchable PSCs, especially that most reports to date describe a decreased mobility when the stretchability is improved. Next, it is determined that improvements to both mobility and stretchability are correlated to the solid‐state molecular ordering and dynamics of coordination bonds under strain, as elucidated via techniques of grazing‐incidence X‐ray diffraction and X‐ray absorption spectroscopy techniques, respectively. This study provides a viable approach to enhance both the mechanical and the electronic performance of polymer‐based soft devices.

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Tuning the Mechanical Properties of a Polymer Semiconductor by Modulating Hydrogen Bonding Interactions

Cited by 92 publications

References 60 publications

A design strategy for high mobility stretchable polymer semiconductors

A design strategy for high mobility stretchable polymer semiconductors

Optimizing the self‐assembly of conjugated polymers and small molecules through structurally programmed non‐covalent control

Metal–Ligand Based Mechanophores Enhance Both Mechanical Robustness and Electronic Performance of Polymer Semiconductors

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