Hierarchically Anisotropic Networks to Decouple Mechanical and Ionic Properties for High-Performance Quasi-Solid Thermocells

Gao, Wei; Lei, Zhouyue; Chen, Wenwen; Liu, Xiangdong

doi:10.1021/acsnano.2c02606

Cited by 49 publications

(56 citation statements)

References 52 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…Apart from above extended applications of sorbents, the efficient utilization and management of the thermal energy produced during the sorption/desorption process could also be meaningful for various technologies. Utilizing the lowgrade thermal energy from the sorption-evaporation cycles combined with advanced electronic devices such as photovoltaic panels [97] and thermal cells [98] has great potential for sustainability. For example, Li et al designed a versatile strategy for the cooling of solar panels in which a sorptionbased atmosphere water harvester served as the cooling component (Figure 16a).…”

Section: Methodsmentioning

confidence: 99%

Sorbents for Atmospheric Water Harvesting: From Design Principles to Applications

et al. 2022

View full text Add to dashboard Cite

Water scarcity caused by climate change and population growth poses a grave threat to human society. Of the different water purification technologies put forward, one presents a promising strategy that is spatially or temporally non‐restricted—atmospheric water harvesting (AWH). Here we review recent progress in the design and study of AWH sorbents, ranging from the innovative chemistries to the integration of sophisticated architectures and functional components, and clarify the structure–property–performance relationship that governs the water capture and release processes. Features and limitations of each type of sorbents are summarized to elucidate the optimal working environments and modes. Progress in applications extending from water generation to thermal management and agriculture are discussed. Future developments regarding material modifications, performance measurements, and system optimizations are provided to overcome lingering barriers to sorbent design and implementation.

show abstract

Section: Methodsmentioning

confidence: 99%

Sorbents for Atmospheric Water Harvesting: From Design Principles to Applications

et al. 2022

View full text Add to dashboard Cite

show abstract

“…47 Figure 5C shows assembled thermocell arrays connected with P-type units in series. The TGCs with 27 P-type units achieve a maximum output power of 28 μW and a total voltage of 342 mV at the ΔT of 10 K. 37 When TECs are connected with P-N types in series, 10 P-N units achieve a voltage of 823.3 mV (Figure 6A). 48 In addition, The TGC enables self-healing properties due to physically crosslinked networks, overcoming the limitation of durability for practical applications (Figure 6B).…”

Section: Wearable Applicationsmentioning

confidence: 99%

Thermoelectric energy harvesting for personalized healthcare

2022

Self Cite

View full text Add to dashboard Cite

In recent decades, there has been increased research interest in miniaturizing and decentralizing diagnostic platforms to enable continuous personalized healthcare and free patients from long‐term hospitalization. However, the lack of reliable and portable power supplies has limited the working time of the personalized healthcare platform. Compared with the current power supplies (e.g., batteries and supercapacitors) that require manual intervention, thermoelectric devices promise to continuously harvest waste heat from the human body to satisfy the energy consumption of personalized healthcare platforms. Herein, this review discusses thermoelectric energy harvesting for personalized healthcare. It begins with the fundamental concepts of different thermoelectric materials, including electron thermoelectric generators (TEGs), ionic thermogalvanic cells (TGCs), and ionic thermoelectric capacitors (TECs). Then, the wearable and implantable applications of thermoelectric devices are presented. Finally, future directions of next‐generation thermoelectric devices for personalized healthcare are discussed. It is hoped that developing high‐performance thermoelectric devices will change the landscape of personalized healthcare in the future.

show abstract

“…Based on the gelatin containing KCl, NaCl, KNO 3 , and Fe(CN) 6 4−/3− , Cheng-Gong et al (2020) gained a prominent thermopower of +17 mV/K through the thermodiffusion of KCl, NaCl, and KNO 3 , as well as the thermogalvanic effect of Fe(CN) 6 4−/3− (Figure 1D). In addition to the studies on the enhancement of thermoelectric performance, the anti-freeze performance (Gao et al, 2021), mechanical properties (Gao et al, 2022), and p-n-type conversion (Duan et al, 2019) are also the focus of research.…”

Section: Performance Enhancement Of Thermogalvanic Cellsmentioning

confidence: 99%

“…Among the state-of-art options, thermogalvanic cells can generate electricity by the gain and loss of electrons at the two same electrodes under the action of a temperature-dependent redox ionic reaction (Lei et al, 2021;Li et al, 2021). In comparison with the conventional electronic thermoelectrics (Taroni et al, 2018;Chae et al, 2020) and ionic thermos capacitors (Al-zubaidi et al, 2017;Wu et al, 2021), thermogalvanic cells based on redox reactions are not only noise-free and environmentally friendly, but also they enable continuous conversion of lowgrade heat to electricity (Gao et al, 2022). Moreover, the thermogalvanic cells hold the potential to enable an efficient, lightweight, continuous flexible power supply for the burgeoning flexible electronics (e.g., flexible screens and wearable medical electronics) (Liu et al, 2022;Peng et al, 2022;Zhang et al, 2022).…”

Section: Introductionmentioning

confidence: 99%

“…Moreover, the thermogalvanic cells hold the potential to enable an efficient, lightweight, continuous flexible power supply for the burgeoning flexible electronics (e.g., flexible screens and wearable medical electronics) (Liu et al, 2022;Peng et al, 2022;Zhang et al, 2022). This imposes the challenge of durably optimizing the performance of thermogalvanic cells in terms of thermopower (Duan et al, 2018), mechanical properties (Lei et al, 2021;Gao et al, 2022;Lei et al, 2022), and anti-freezing (Gao et al, 2021), among others. Although the previous researchers presented significant advances, thermogalvanic cells still have challenges in the field of low-grade heat harvesting and flexible power sources.…”

Section: Introductionmentioning

confidence: 99%

See 1 more Smart Citation