Highly Stable Photo‐Assisted Zinc‐Ion Batteries via Regulated Photo‐Induced Proton Transfer

Zha, Wenwen; Ruan, Qiushi; Ma, Long; Liu, Meng; Lin, Huiwen; Sun, Litao; Sun, ZhengMing; Tao, Li

doi:10.1002/anie.202400621

Cited by 3 publications

(2 citation statements)

References 52 publications

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“…Recently, Sun et al chose widely used V 2 O 5 , identifying that photoinduced proton transfer in the photo-(dis)charge process is a significant reason for cycling instability. 84 They regulated photoinduced proton transfer through electrode surface engineering, enabling a highcyclability light-responsive Zn-ion battery. In addition to vanadium oxide, Zn-ion batteries employing MoS 2 as photoactive materials have been proposed.…”

Section: Accelerating Sluggish Reaction Kineticsmentioning

confidence: 99%

“…Although light-responsive Zn-ion batteries have exhibited desired solar energy conversion and storage capability, cycling instability upon illumination is still an open challenge. Recently, Sun et al chose widely used V 2 O 5 , identifying that photoinduced proton transfer in the photo(dis)charge process is a significant reason for cycling instability . They regulated photoinduced proton transfer through electrode surface engineering, enabling a high-cyclability light-responsive Zn-ion battery.…”

Section: Metal Batteries Boosted By Lightmentioning

confidence: 99%

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Boosting Energy Storage in Metal Batteries by Light: Progress, Challenges, and Perspectives

Chen,

Zhen,

2024

Energy Fuels

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Metal batteries with high theoretical capacities have become more important than ever in pursuing carbon-neutral initiatives to reduce fossil energy consumption and incorporate intermittent renewable energy into the electric grid. However, cathode materials often encounter significant challenges, such as sluggish reaction kinetics, limited capacities, or low operation voltages, limiting the practical applications of these batteries. Inspired by light− matter interactions that might provoke a photoelectric or photothermal effect on lightresponsive materials, various light-responsive batteries have been developed by introducing photoactive materials to convert solar energy into electrical (or thermal) energy, addressing the issues facing cathode materials. Despite the fact that some reviews have been published to summarize the advances in light-responsive batteries with the rapid development of the rising field, the basic working principles of light-responsive batteries are still not well elucidated in detail. In this review, we first give a summary of the understanding of the photoelectric and photothermal effects and correlate their parameters with the metrics (voltage, capacity, and kinetics) of light-responsive batteries. Then, we provide representative examples of light-responsive batteries to support the understanding. Finally, the challenges in the development of light-responsive metal batteries are discussed. Accordingly, potential directions and key perspectives for light-responsive metal batteries are also proposed in the hope of guiding their design and optimization for accelerating practical application.

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Section: Accelerating Sluggish Reaction Kineticsmentioning

confidence: 99%

Section: Metal Batteries Boosted By Lightmentioning

confidence: 99%

Boosting Energy Storage in Metal Batteries by Light: Progress, Challenges, and Perspectives

Chen,

Zhen,

2024

Energy Fuels

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Developing a Multifunctional Cathode for Photoassisted Lithium–Sulfur Battery

Zhao,

Yang,

Liu

et al. 2024

Advanced Science

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Integration of solar cell and secondary battery cannot only promote solar energy application but also improve the electrochemical performance of battery. Lithium–sulfur battery (LSB) is an ideal candidate for photoassisted batteries owing to its high theoretical capacity. Unfortunately, the researches related the combination of solar energy and LSB are relatively lacking. Herein, a freestanding photoelectrode is developed for photoassisted lithium–sulfur battery (PALSB) by constructing a heterogeneous structured Au@N‐TiO2 on carbon cloths (Au@N‐TiO2/CC), which combines multiple advantages. The Au@N‐TiO2/CC photoelectrode can produce the photoelectrons to facilitate sulfur reduction during discharge process, while generating holes to accelerate sulfur evolution during charge process, improving the kinetics of electrochemical reactions. Meanwhile, Au@N–TiO2/CC can work as an electrocatalyst to promote the conversion of intermediate polysulfides during charge/discharge process, mitigating induced side reactions. Benefiting from the synergistic effect of electrocatalysis and photocatalysis, PALSB assembled with an Au@N‐TiO2/CC photoelectrode obtains ultrahigh specific capacity, excellent rate performance, and outstanding cycling performance. What is more, the Au@N‐TiO2/CC assembled PALSB can be directly charged under light illumination. This work not only expands the application of solar energy but also provides a new insight to develop advanced LSBs.

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An Efficient MnO₂ Photocathode with an Excellent SnO₂ Electron Transport Layer for Photo‐Accelerated Zinc Ion Batteries

Gao,

Tian,

Shi

et al. 2024

Small

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Photo‐accelerated rechargeable batteries play a crucial role in fully utilizing solar energy, but it is still a challenge to fabricate dual‐functional photoelectrodes with simultaneous high solar energy harvesting and storage. This work reports an innovative photo‐accelerated zinc‐ion battery (PAZIB) featuring a photocathode with a SnO2@MnO2 heterojunction. The design ingeniously combines the excellent electronic conductivity of SnO2 with the high energy storage and light absorption capacities of MnO2. The capacity of the SnO2@MnO2‐based PAZIB is ≈598 mAh g−1 with a high photo‐conversion efficiency of 1.2% under illumination at 0.1 A g−1, which is superior to that of most reported MnO2‐based ZIB. The boosting performance is attributed to the synergistic effect of enhanced photogenerated carrier separation efficiency, improved conductivity, and promoted charge transfer by the SnO2@MnO2 heterojunction, which is confirmed by systematic experiments and theoretical simulations. This work provides valuable insights into the development of dual‐function photocathodes for effective solar energy utilization.

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Highly Stable Photo‐Assisted Zinc‐Ion Batteries via Regulated Photo‐Induced Proton Transfer

Cited by 3 publications

References 52 publications

Boosting Energy Storage in Metal Batteries by Light: Progress, Challenges, and Perspectives

Boosting Energy Storage in Metal Batteries by Light: Progress, Challenges, and Perspectives

Developing a Multifunctional Cathode for Photoassisted Lithium–Sulfur Battery

An Efficient MnO₂ Photocathode with an Excellent SnO₂ Electron Transport Layer for Photo‐Accelerated Zinc Ion Batteries

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Highly Stable Photo‐Assisted Zinc‐Ion Batteries via Regulated Photo‐Induced Proton Transfer

Cited by 3 publications

References 52 publications

Boosting Energy Storage in Metal Batteries by Light: Progress, Challenges, and Perspectives

Boosting Energy Storage in Metal Batteries by Light: Progress, Challenges, and Perspectives

Developing a Multifunctional Cathode for Photoassisted Lithium–Sulfur Battery

An Efficient MnO2 Photocathode with an Excellent SnO2 Electron Transport Layer for Photo‐Accelerated Zinc Ion Batteries

Contact Info

Product

Resources

About

An Efficient MnO₂ Photocathode with an Excellent SnO₂ Electron Transport Layer for Photo‐Accelerated Zinc Ion Batteries