Stretchable and Healable Conductive Elastomer Based on PEDOT:PSS/Natural Rubber for Self-Powered Temperature and Strain Sensing

Yang, Yan; Zhao, Guojie; Cheng, Xi; Deng, Hua; Fu, Qiang

doi:10.1021/acsami.1c00879

Cited by 76 publications

(68 citation statements)

References 47 publications

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“…On account of considering to enhance both stretchability and thermoelectric performance, Yang et al proposed a composite film incorporating PEDOT:PSS treated by EG and DMSO with natural rubber (NR), then treated by water and phosphatebuffered saline to realize strain and conductivity recovery (Figure 3a). [43] The composite film with 10 wt% PEDOT:PSS possessed electrical conductivity of 4.1 S cm −1 and 31 µV K −1 Seebeck coefficient (Figure 3b). The composite film exhibited brilliant strain sensing performance at even 100% tensile strain (Figure 3c) and presented wrinkles under the free state due to the interlacing of rubber particles.…”

Section: Blending With Elastic Materialsmentioning

confidence: 99%

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Stretchable Thermoelectrics: Strategies, Performances, and Applications

Wang

et al. 2021

Adv Funct Materials

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With the rapid development of intelligent devices, flexible robots, medical monitors, and electronic skins, stretchable wireless power supplies are in great demand. Thermoelectric devices have proven to be promising candidates for wearable electronics owing to their significant conversion capability from low-grade waste heat in the environment to electric energy. Therefore, stretchable thermoelectric generators attract widespread attention and remarkable progress has been made recent years. In this review, various design strategies are comprehensively overviewed from the perspective of material composition design and structure design for enhanced stretchability of thermoelectric materials and devices. Furthermore, the thermoelectric performance and multifunctional applications of stretchable materials and devices are emphasized. Finally, the challenges and prospects in the development and applications of stretchable thermoelectrics are presented.

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Section: Blending With Elastic Materialsmentioning

confidence: 99%

“…d) Surface SEM images of 10 wt% composite films under various tensile strains. e) Morphology deformation of the composite films under tensile strain.Reproduced with permission [43]. Copyright 2021, American Chemical Society.…”

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confidence: 99%

Stretchable Thermoelectrics: Strategies, Performances, and Applications

Wang

et al. 2021

Adv Funct Materials

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“…For example, Qiu et al [88] reported a dual-mode sensor based on interlocked piezoresistive and piezoelectric films, realizing the complementary performance of the two sensing mechanisms, and thus improving the sensitivity and broadening the sensing range [Figure 5A]. Hwang et al [89] reported a transparent sensor combining piezoresistive and capacitive transduction mechanisms, which can distinguish touch and pressure, as shown in Figure 5B. Besides the direct combination of two sensing mechanisms in a single device design, a single sensor can respond to a variety of stimuli by selecting specific functional materials.…”

Section: From Single-mode Sensor To Multi-mode Tactile Sensormentioning

confidence: 99%

“…(B) Schematic diagram and current versus time of the transparent dual-mode sensor, which can distinguish touch and pressure. Reproduced with permission from Ref [89]. .…”

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confidence: 99%

Recent progress in flexible tactile sensor systems: from design to application

Zhu¹,

Zhou²,

Zhang³

2021

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With the rapid development of artificial intelligence, human-machine interaction, and healthcare systems, flexible tactile sensors have huge market potentials and research needs, so that both fundamental research and application demonstrations are evolving rapidly to push the potential to reality. In this review, we briefly summarize the recent progress of the flexible tactile sensor system, including the common sensing mechanisms, the important performance evaluation parameters, the device design trend, and the main applications. Moreover, the current device design trend towards flexible tactile sensor systems is discussed, including novel structures for outstanding performance, sensor arrays for large-area information acquisition, multi-mode information acquisition, and integration of tactile sensors with transistors. Various emerging applications enabled with these sensors are also exemplified in this review to show the potentials of the tactile sensors. Finally, we also discuss the technical demands and the future perspectives of flexible tactile sensor systems.

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“… 34 Such polymer based composites are generally fabricated using in situ , chemical oxidation, vapor phase polymerization, and chemical exfoliation, 35–37 whereas the filler are widely mixed with different organic solvents, reducing agents, dispersing agents and stabilizers. 38 The features of the intrinsic conductive polymers are not only limited to their potential electrical and thermal properties but due to their light weight, flexibility and higher stability against water, and air makes them highly suitable for super capacitors, batteries, solar cells, and other energy storage and harvesting devices. 39 Furthermore, chemical functionalization and in situ solution processed polymer composite are commonly used including screen printing, ink jet printing dispenser printing; spray printing, and spin coating, 40,41 as an efficient, cost-effective method to fabricate TE devices on mass scale.…”

Section: Introductionmentioning

confidence: 99%