Stretchable Nanolayered Thermoelectric Energy Harvester on Complex and Dynamic Surfaces

Yang, Yang; Hu, Hongjie; Chen, Zeyu; Wang, Ziyu; Jiang, Laiming; Lu, Guoxing; Li, Xiangjia; Chen, Ruimin; Jin, Jie; Kang, Haochen; Chen, Hengxi; Lin, Shuang; Xiao, Siqi; Zhao, Hao; Xiong, Rui; Shi, Jing; Zhou, Qifa; Xu, Sheng; Chen, Yong

doi:10.1021/acs.nanolett.0c01225

Cited by 136 publications

(124 citation statements)

References 48 publications

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“…[10] Among these power sources, thermoelectric generators (TEG) attached to the human body are highly attractive, as the heat continually being emitted by the body (up to 20 mW cm −2 ) enables a constant power supply, in contrast to motion-based, or solar-based energy harvesting technologies. [10][11][12][13]16,17] We have recently discussed the promising prospect of body heat harvesting in the future global market of wearable electronics and provided possible designs for a skin-conformal TEG. [10] However, the relatively low Seebeck coefficient (S e = ∆V/∆T, where ∆V is the open circuit voltage and ∆T is the temperature gradient) on the order of µV K −1 [18] and the reliance on rigid and expensive thermoelectric materials have greatly limited the practical development of TEGs for wearable applications.…”

Section: Introductionmentioning

confidence: 99%

Advanced Wearable Thermocells for Body Heat Harvesting

Liu

Zhang

Zhou

et al. 2020

Advanced Energy Materials

120

149

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Thermoelectrochemical cells (thermocells) designed for harvesting human body heat can provide constant power output for wearable electronics, supplementing state‐of‐the‐art flexible power storage and conversion solutions. However, a systematic investigation into the optimization of wearable thermocells is lacking, especially with regard to device design, n‐type electrolytes, and electrode/electrolyte integration. Here, a n‐type gel electrolyte: polyvinyl alcohol‐FeCl2/3 with outstanding flexibility and elasticity and exceptional electrolyte/electrode integration into a 3D porous poly(3,4‐ethylenedioxythiophene)/polystyrenesulfonate (PEDOT/PSS) electrode, is produced via an in situ chemical crosslinking method. The integrated n‐type cell shows excellent seebeck coefficients (0.85 mV K−1) and output current density (1.74 A m−2 K−1) that are comparable with an optimized p‐type cell consisting of a carboxymethylcellulose‐K3/4Fe(CN)6 electrolyte with a 3D PEDOT/PSS‐edge functionalized graphene/carbon nanotube electrode (−1.22 mV K−1 and 1.85 A m−2 K−1). The equivalent performance of the n‐type and p‐type cells enables the effective series connection of up to 18 pairs of p–n cells that combines to give an output voltage of 0.34 V (∆T = 10 K). This in‐series device is fabricated into a proof‐of‐concept watch strap, which can harvest body heat, charge supercapacitor (up to 470 mF) as well as illuminate a green light emitting diode, demonstrating the practical applications.

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Section: Introductionmentioning

confidence: 99%

Advanced Wearable Thermocells for Body Heat Harvesting

Liu

Zhang

Zhou

et al. 2020

Advanced Energy Materials

120

149

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Section: Performancementioning

confidence: 99%

“…[191][192][193] Finally, several groups used integrated rigid thermoelectric legs in a flexible platform to create flexible devices. [176,[194][195][196][197][198][199][200][201][202][203] Flexible TEGs relying on the deposition of thin-film materials on flexible substrates are not stretchable since the deposited materials are rigid in nature, but can be flexible if they are thin enough. Additionally, in most cases, the temperature difference across the thin-film thermoelectric materials is small (if the heat flows through the thickness of the material), which results in low open-circuit voltage.…”

Section: Design Approachesmentioning

confidence: 99%

“…Since then, several studies reported various flexible TEGs incorporating rigid thermoelectric blocks. [176,[194][195][196][197][198][199][200][201][202][203] Such blocks can be interconnected using thin Cu traces. [200] Importantly, the space between the thermoelectric blocks should be electrically and thermally insulating; the latter helps to force heat to travel through the thermoelectric materials.…”

Section: Flexible Tegs Using Rigid Bulk Materialsmentioning

confidence: 99%

“…[176] Stretchable interconnects help to improve the durability and performance of rigid TEG materials embedded in silicone. By using spiral Cu electrodes, it is possible to create more robust interconnects to rigid materials, such as Sb 2 Te 3 and Bi 2 Te 3 embedded in a silicone platform, [202] as shown in Figure 6J. This TEG produced 1.5 W m −2 at a temperature gradient of 19 °C.…”

Section: Flexible Tegs Using Rigid Bulk Materialsmentioning

confidence: 99%

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Energy Harvesting and Storage with Soft and Stretchable Materials

et al. 2021

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Soft robotics can interact with humans safely. 3) Devices built from stretchable materials have a greater mechanical degree of freedom. This allows electronics, displays, and sensors to be integrated into places that would be difficult or impossible with rigid devices and enables new types of human-computer interfaces. It also allows robotics to have enhanced levels of dexterity and complexity in movement (consider the octopus as an inspiring example). 4) Devices that can be deformed elastically can be engineered to have new or emerging properties, such as antennas that change frequency with elongation, [21] intelligent materials that can perform unconventional forms of logic, [22,23] or composites that change thermal conductivity, [24] electrical conductivity, [25] or dielectric properties with deformation. [26][27][28] Most robotic and electronic devices require electricity to function, as shown on the left side of Figure 1A. Electricity can power sensors, enable computation, drive locomotion, and transmit information. Although most devices use electricity from an outlet, such "tethered" devices create notable limitations. In addition to limiting the degree of freedom of robotic materials, plug-in devices must be within a chords-length of a functioning outlet, thereby confining the range of use of such devices. Although battery operated devices can operate for some time without being plugged-in, the need to do so periodically is at best a nuisance that limits the operating time of a device. At worst, it can lead to issues such as lack of compliance with wearable devices (that is, the device is taken off for charging and never put back on) or disruptions in operation (a particular problem for health care devices or remotely deployed devices). Thus, there is a compelling interest in harvesting energy from the ambient to create tetherless devices or even devices that need less charging. Figure 1A (right side) provides examples of applications that may benefit from harvesting, such as internetof-things (IOT) devices, soft robots, wearables, implantables, and deployables (that is, devices sent to remote locations that do not have electrical outlets). Energy Harvesting CategoriesStrategies to harness energy typically convert waste or otherwise unused energy from the ambient into electricity. Although This review highlights various modes of converting ambient sources of energy into electricity using soft and stretchable materials. These mechanical properties are useful for emerging classes of stretchable electronics, e-skins, bio-integrated wearables, and soft robotics. The ability to harness energy from the environment allows these types of devices to be tetherless, thereby leading to a greater range of motion (in the case of robotics), better compliance (in the case of wearables and e-skins), and increased application space (in the case of electronics). A variety of energy sources are available including mechanical (vibrations, human motion, wind/fluid motion), electromagnetic (radio frequency (RF), solar), and ther...

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Self‐Powered Sensors for Wearable Detections

Zou,

2024

Portable and Wearable Sensing Systems

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Stretchable Nanolayered Thermoelectric Energy Harvester on Complex and Dynamic Surfaces

Cited by 136 publications

References 48 publications

Advanced Wearable Thermocells for Body Heat Harvesting

Advanced Wearable Thermocells for Body Heat Harvesting

Energy Harvesting and Storage with Soft and Stretchable Materials

Self‐Powered Sensors for Wearable Detections

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