The resistance of solar photothermal ASS lithium-air battery (after 10 min solar irradiation) is ~10-2 of common ASS lithium-air battery (without light irradiation) operating at -73 ℃. According to the discharge behavior of the battery under solar irradiation (Fig. 1b), the rise of light-induced temperature is direct related to the reactivation of our battery. As shown in Fig.
A facile route that combines co-assembly and photothermal reduction was developed to synthesize free-standing, flexible FeF(3)-graphene papers, which demonstrate promising applications as cathodes in high-energy density Li-ion batteries. A facile route that combines co-assembly and photothermal reduction was developed to synthesize free-standing, flexible
Lithium-ion batteries (LIBs) suffer from charging difficulties, capacity decay, and severe ageing in a low-temperature environment. In this work, we suggest a theoretical study and strategy for improving the low-temperature resistance of LiMn2O4(LMO) pouch cells, by introducing a photothermal conversion layer composed of copper and single
Poly(ethylene oxide)-based polymer all-solid-state Li S battery is a promising candidate due to its high specific energy, good processability, and low cost. However, the poor room temperature ionic conductivity limits its
Lithium, one of the most valuable resources, has found its way into various industries, ranging from ceramics, glass, pharmaceuticals, and nuclear to the booming lithium battery technology 1,2,3,4
Request PDF | Solar-driven all-solid-sate lithium-air batteries operating at extreme low temperatures | We propose an innovative solar photothemal battery technology to develop all-solid-sate
Solid-state LiFePO4|Li batteries with electrolytes of "ceramic-in-polymer" and "polymer-in-ceramic" deliver excellent cycling stability with high discharge capacities (139.1 mAh g–1 with
a) Schematic diagram of solar photothermal All-solid-state lithium-air battery where black air cathode is strongly anchored on the Li 1.5 Al 0.5 Ge 1.5 (PO 4) 3 (LAGP) electrolyte. b) Temperature change curves of lithium-air battery at −73 °C under Xe-lamp irradiation.
Lithium-ion batteries (LIBs) suffer from charging difficulties, capacity decay, and severe ageing in a low-temperature environment. In this work, we suggest a theoretical study and strategy for improving the low
A three-dimensional electrochemical–thermal coupling model for a lithium manganate battery is established, in which the photothermal conversion layer is attached on the surface of the cathode...
Here, an innovative strategy of light-mediated energy conversion is reported to build photothermal-based SPEs (PT-SPEs). The results suggest that the nanostructured photothermal materials acting as a powerful light-to-heat converter enable heating within a submicron space, leading to a decreased Li + migration barrier and a stronger solid
Here, an innovative strategy of light-mediated energy conversion is reported to build photothermal-based SPEs (PT-SPEs). The results suggest that the nanostructured photothermal materials acting as a powerful light-to-heat
Lithium (Li) and its compounds are key materials to lithium-ion batteries (LIBs). The demand for LIBs and Li resources are booming recently due to the rapid growth of electric vehicles, personal electronic devices, and grid-scale energy storage systems [1].
Here, we devise and implement a new technology exploiting excitons-based light-to-heat conversion promoted by WS 2 nanofillers in nanocomposite polymeric membranes for sunlight-driven photothermal membrane crystallization, applied for the efficient extraction of lithium from Li-rich brines.
In this review, first, the mechanism of lithium extraction with photothermal evaporation is fully summarized, involving membrane separation, lithium-ion sieves, and
Lithium (Li) and its compounds are key materials to lithium-ion batteries (LIBs). The demand for LIBs and Li resources are booming recently due to the rapid growth of electric
In this review, first, the mechanism of lithium extraction with photothermal evaporation is fully summarized, involving membrane separation, lithium-ion sieves, and separated crystallization. Second, a series of strategies for designing various evaporators with highly efficient lithium adsorption characteristics based on photothermal
Lithium-ion batteries (LIBs) and plastics are pivotal components of modern society; nevertheless, their escalating production poses formidable challenges to resource sustainability and ecosystem integrity. Here, we showcase the transformation of spent lithium cobalt oxide (LCO) cathodes into photothermal catalysts capable of catalyzing the upcycling of
In this work, we study Prussian blue analogues (PBAs), which are known to have a high photothermal heating efficiency and can be used as cathodes for Li-ion batteries. PBAs were synthesized directly on a carbon collector electrode and tested under different thermally controlled conditions to show the effect of photothermal heating on battery
A three-dimensional electrochemical–thermal coupling model for a lithium manganate battery is established, in which the photothermal conversion layer is attached on the surface of the cathode...
Solid-state LiFePO4|Li batteries with electrolytes of "ceramic-in-polymer" and "polymer-in-ceramic" deliver excellent cycling stability with high discharge capacities (139.1
[1-5] Lithium metal batteries (LMBs) have been considered as one of the promising next-generation rechargeable batteries due to high theoretical specific capacity (3860 mAh g −1) and the lowest negative redox potential (–3.04 V vs standard hydrogen electrode) of lithium metal anode. Exploring the LMBs with excellent cycling stability and high energy
This study demonstrates the stable operation of aqueous batteries in subzero conditions by integrating high-efficiency photothermal current collectors with suspension electrodes. The
This study demonstrates the stable operation of aqueous batteries in subzero conditions by integrating high-efficiency photothermal current collectors with suspension electrodes. The Ketjen black-based photothermal current collectors efficiently convert a broad spectrum of sunlight (98%, 200–2500 nm) into thermal energy, enabling rapid heat
In this work, we study Prussian blue analogues (PBAs), which are known to have a high photothermal heating efficiency and can be used as cathodes for Li-ion batteries.
Common methods for directly extracting lithium from salt lakes include precipitation, electrodialysis, and photothermal evaporation. Among these methods, lithium extraction using photothermal evaporation is considered an efficient and clean approach to addressing lithium shortages. In recent years, a lot of progress is made regarding lithium
The core innovation of this study is the integration of photothermal materials within the battery''s current collectors, allowing it to self-heat and operate effectively at low temperatures. The Ketjen black-based collectors absorb sunlight across a wide spectrum (98% efficiency from 200 to 2,500 nm), quickly generating heat that raises the battery''s core
Here, we devise and implement a new technology exploiting excitons-based light-to-heat conversion promoted by WS 2 nanofillers in nanocomposite polymeric
Poly(ethylene oxide)-based polymer all-solid-state Li S battery is a promising candidate due to its high specific energy, good processability, and low cost. However, the poor room temperature ionic conductivity limits its further development. Here an innovative photothermal battery technology is proposed to realize the normal
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