Polymer-Infused Textile Thermoelectrics for Power Generation

Chauhan, Avnee; Kumar, Santosh; Satapathy, Dillip K.; Battabyal, Manjusha

doi:10.1021/acsaelm.4c00352

Cited by 3 publications

(1 citation statement)

References 42 publications

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“…Conducting polymers (CPs) like PEDOT:PSS, polyaniline (PANI), poly(ethylene terephthalate) (PET), and their composites are widely explored in the field of flexible TE. , The composites processed out of CPs and inorganic TE materials can take advantage of good TE properties of the inorganic, low κ value, and flexibility of the CP . Instead of CPs, nonconducting polymers like nylon, polyimide, and so on are also being explored in the field of flexible TE, which provides flexibility to the deposited inorganic TE films on it. − However, ink printing is an emerging scope in the field of flexible TE because of its ease of processing, cost-effectiveness, and ease of scale.…”

Section: Introductionmentioning

confidence: 99%

High-Performance Printed Ag₂Se/PI Flexible Thermoelectric Film for Powering Wearable Electronics

Kumar,

Battabyal,

Sethupathi

et al. 2024

ACS Appl. Mater. Interfaces

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We report the magnificent thermoelectric properties of the n-type Ag 2 Se film printed onto a flexible polyimide (PI) substrate. The orthorhombic β-Ag 2 Se phase of the processed Ag 2 Se film is confirmed from the X-ray diffractogram. Remarkably, the resulting Ag 2 Se/PI film exhibits outstanding thermoelectric properties, boasting maximum power factors of 1.4 and 2.1 mW/mK 2 at 300 and 405 K, respectively. Furthermore, the flexibility of the Ag 2 Se/PI film remains intact even after undergoing 1500 bending cycles with no degradation observed in its thermoelectric performance. To demonstrate the practical application of our findings, a flexible thermoelectric prototype is constructed using the fabricated Ag 2 Se/PI films, which can harvest an impressive output voltage of 52 mV across a temperature difference of 53 K. Additionally, the prototype generates a maximum power output of 7.2 μW with a 40 K temperature difference and can produce 13 mV output voltage when subjected to around a 10 K temperature gradient when the cold side temperature is maintained at 308 K. Moreover, leveraging body heat with just a 1 K temperature variance between the body and the surrounding environment, the prototype could yield an impressive voltage output of 1.6 mV, marking the highest reported voltage output from human body heat to date. Our study not only introduces a cost-effective method for producing highperformance flexible thermoelectric films but also highlights their potential applications in wearable and implantable electronics.

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Section: Introductionmentioning

confidence: 99%

High-Performance Printed Ag₂Se/PI Flexible Thermoelectric Film for Powering Wearable Electronics

Kumar,

Battabyal,

Sethupathi

et al. 2024

ACS Appl. Mater. Interfaces

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Flexible Ag₂Se Film with Enhanced Thermoelectric Performance

Kumar,

Battabyal,

Satapathy

2024

ACS Appl. Mater. Interfaces

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Flexible thermoelectric devices offer huge potential for wearable electronics due to their ability to generate green energy by using low-grade heat. However, achieving both high thermoelectric performance and flexibility simultaneously remains a challenge for these devices. Here, we present a simple and cost-effective method for fabricating a high-performance flexible inorganic−organic thermoelectric film by depositing Ag 2 Se on a porous nylon membrane. The resulting Ag 2 Se/nylon film exhibits an ultrahigh power factor of approximately 3.4 mW/mK 2 at 300 K, the highest value reported for flexible thermoelectric films to date. The Ag 2 Se/nylon film also demonstrates remarkable flexibility, confirming its potential application in wearable electronics. A thermoelectric module constructed using eight strips of the processed Ag 2 Se/nylon film generates an impressive output voltage of 65 mV and an output power of 30 μW at a 30 K temperature difference. Additionally, the fabricated module maintains strong flexibility, producing more than 2 mV when wrapped around a human arm with a temperature difference of 1.6 K. This work highlights the significant potential of inorganic−organic films for flexible thermoelectric applications in wearable and implantable devices.

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Recent advances in enhancing thermoelectric performance of polymeric materials

Mulla,

Chapi

2024

Polymers from Renewable Resources

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The inherent low thermal conductivity, low cost, and flexibility of polymeric materials make them potential candidates for thermoelectric applications. Their eco-friendliness and mechanical flexibility are useful for the design of portable and flexible self-powered electronics. However, the heat-to-electrical power conversion efficiency, also known as the figure-of-merit (ZT), of polymer TE materials is low. Research efforts are in progress to enhance the thermoelectric performance of polymers and to find new kinds of polymer composites. Recent research innovations, such as chemical doping of polymers, development of nanocomposites and hybrid composites, and nanostructuring have significantly changed the thermoelectric properties of the polymeric materials. In this article, we summarize the recent developments and achievements in polymer materials for thermoelectric applications.

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Polymer-Infused Textile Thermoelectrics for Power Generation

Cited by 3 publications

References 42 publications

High-Performance Printed Ag₂Se/PI Flexible Thermoelectric Film for Powering Wearable Electronics

High-Performance Printed Ag₂Se/PI Flexible Thermoelectric Film for Powering Wearable Electronics

Flexible Ag₂Se Film with Enhanced Thermoelectric Performance

Recent advances in enhancing thermoelectric performance of polymeric materials

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Polymer-Infused Textile Thermoelectrics for Power Generation

Cited by 3 publications

References 42 publications

High-Performance Printed Ag2Se/PI Flexible Thermoelectric Film for Powering Wearable Electronics

High-Performance Printed Ag2Se/PI Flexible Thermoelectric Film for Powering Wearable Electronics

Flexible Ag2Se Film with Enhanced Thermoelectric Performance

Recent advances in enhancing thermoelectric performance of polymeric materials

Contact Info

Product

Resources

About

High-Performance Printed Ag₂Se/PI Flexible Thermoelectric Film for Powering Wearable Electronics

High-Performance Printed Ag₂Se/PI Flexible Thermoelectric Film for Powering Wearable Electronics

Flexible Ag₂Se Film with Enhanced Thermoelectric Performance