Tactile UV‐ and Solar‐Light Multi‐Sensing Rechargeable Batteries with Smart Self‐Conditioned Charge and Discharge

Fang, Zhengsong; Zhang, You; Hu, Xuanhe; Fu, Xinlong; Dai, Liming; Yu, Dingshan

doi:10.1002/ange.201903805

Cited by 14 publications

(11 citation statements)

References 37 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…[50] In general, in addition to catalytic active sites, the catalytic property of catalysts is also related with the electron and ion transport. [36] Thus, in our case, the photoresponsiveness of PANINA in Mode 3 mainly comes from the photothermal effect, which triggers local temperature rise to facilitate the electron and ion transport, thereby improving the ORR catalytic reaction rate of PANINA cathodes and the battery performance, similar to previous studies. [35][36][37] The improved redox kinetics is also confirmed by the EIS result that that charge transfer resistance is significantly reduced from 63.7 to 3.9 Ω under the light illumination (Figure S23, Supporting Information).…”

Section: (3 Of 11)supporting

confidence: 85%

“…[36] Thus, in our case, the photoresponsiveness of PANINA in Mode 3 mainly comes from the photothermal effect, which triggers local temperature rise to facilitate the electron and ion transport, thereby improving the ORR catalytic reaction rate of PANINA cathodes and the battery performance, similar to previous studies. [35][36][37] The improved redox kinetics is also confirmed by the EIS result that that charge transfer resistance is significantly reduced from 63.7 to 3.9 Ω under the light illumination (Figure S23, Supporting Information). Importantly, when the battery is subjected to periodic illumination, one can see repeatable and reliable photoresponsiveness toward the discharge (Figure 5e).…”

Section: (3 Of 11)supporting

confidence: 85%

“…[49,50] Similar phenomenon was also observed in previously reported photoassisted supercapacitors [50] and Zn-air batteries. [35][36][37] This is verified by the electrochemical impedance spectroscopy (EIS) analysis (Figure 2f) that exhibits reduced charge and ion transfer resistances after light illumination. [50] Taken together, rational micro/nanostructural engineering of active PANINA layers and integrated cathode design coupled with the photothermal effect enables the full demonstration the PANI electroactivity in near-neutral media, establishing a new type of light-assisted electrically rechargeable Zn-PANINA battery with remarkably improved specific capacity.…”

Section: (3 Of 11)mentioning

confidence: 81%

“…[1][2][3][4][5][6][7] To this end, aqueous rechargeable zinc (Zn) batteries have become a hot research subject owing to their large theoretical capacity (820 mAh g −1 ) and environmental-friendliness, high earth abundance of zinc, and high ionic conductivity On one hand, such integrated system could enable the direct compensation of energy consumption for energy storage units and realize self-charging without extra electricity input. On the other hand, the incorporation of desirable environmental energies (e.g., solar energy) into various batteries such as Zn-air batteries, [35][36][37] Li-ion batteries, [21][22][23] and Li-O 2 batteries [38,39] can improve the energy storage and conversion performance. Noteworthy, different from other environmental energies, air is pervasive with nearly constant concentration, rendering its potential use as a readily-available "energy resource" for various energy devices.…”

Section: Introductionmentioning

confidence: 99%

See 3 more Smart Citations

Harvesting Air and Light Energy via “All‐in‐One” Polymer Cathodes for High‐Capacity, Self‐Chargeable, and Multimode‐Switching Zinc Batteries

Xie

Fang

Yang

et al. 2021

Adv Funct Materials

Self Cite

View full text Add to dashboard Cite

Aqueous rechargeable Zinc (Zn)–polymer batteries are promising alternatives to prevalent Li‐ion cells in terms of cost, safety, and rate capability but they suffer from limited specific capacity in addition to poor environmental adaptability. Herein, air and light are successfully utilized from external environments in single near‐neutral two‐electrode Zn batteries to enable remarkably improved electrochemical performance, fast self‐charging, and switchable multimode‐operation from Zn–polymer to Zn–air cells. This system is enabled by a well‐designed polyaniline‐nanorod‐array based “all‐in‐one” cathode combining reversible redox capability, oxygen reduction activity, and photothermal‐responsiveness. The initiative design allows perfect integration of multiple energy harvesting from ambient “air” and light, energy conversion, and storage in one single cathode. Thus, it can act as an efficient light‐assisted electrically‐rechargeable Zn–polymer cell featuring the highest specific capacity of 430.0 mAh g−1 among all existing polymer cathodes. Without external power sources, it can be self‐charged to deliver a high discharging capacity of 363.1 mAh g−1 by concurrently harvesting chemical energy from air and light energy for only 20 min. It can also switch to a light‐responsive Zn–air battery mode to surmount the output capacity limit of Zn–polymer battery mode for continued electricity supply.

show abstract

Section: (3 Of 11)supporting

confidence: 85%

Section: (3 Of 11)supporting

confidence: 85%

Section: (3 Of 11)mentioning

confidence: 81%

Section: Introductionmentioning

confidence: 99%

See 2 more Smart Citations

Harvesting Air and Light Energy via “All‐in‐One” Polymer Cathodes for High‐Capacity, Self‐Chargeable, and Multimode‐Switching Zinc Batteries

Xie

Fang

Yang

et al. 2021

Adv Funct Materials

Self Cite

View full text Add to dashboard Cite

show abstract

“…4% of the solar spectrum (14)(15)(16). Expanding the light harvesting from UV to visible light is the longterm goal and challenge of photocatalysis (17)(18)(19)(20). Simultaneously, high carrier recombination consumes the majority of photoelectrons and holes before catalyzing the targeted reactions, resulting in a mismatch between the carrier lifetime and kinetics of ORR or OER (19)(20)(21).…”

mentioning

confidence: 99%

Surface plasmon mediates the visible light–responsive lithium–oxygen battery with Au nanoparticles on defective carbon nitride

Zhu

et al. 2021

Proc. Natl. Acad. Sci. U.S.A.

View full text Add to dashboard Cite

Aprotic lithium-oxygen (Li-O2) batteries have gained extensive interest in the past decade, but are plagued by slow reaction kinetics and induced large-voltage hysteresis. Herein, we use a plasmonic heterojunction of Au nanoparticle (NP)–decorated C3N4 with nitrogen vacancies (Au/NV-C3N4) as a bifunctional catalyst to promote oxygen cathode reactions of the visible light–responsive Li-O2 battery. The nitrogen vacancies on NV-C3N4 can adsorb and activate O2 molecules, which are subsequently converted to Li2O2 as the discharge product by photogenerated hot electrons from plasmonic Au NPs. While charging, the holes on Au NPs drive the reverse decomposition of Li2O2 with a reduced applied voltage. The discharge voltage of the Li-O2 battery with Au/NV-C3N4 is significantly raised to 3.16 V under illumination, exceeding its equilibrium voltage, and the decreased charge voltage of 3.26 V has good rate capability and cycle stability. This is ascribed to the plasmonic hot electrons on Au NPs pumped from the conduction bands of NV-C3N4 and the prolonged carrier life span of Au/NV-C3N4. This work highlights the vital role of plasmonic enhancement and sheds light on the design of semiconductors for visible light–mediated Li-O2 batteries and beyond.

show abstract

Photo‐excited Oxygen Reduction and Oxygen Evolution Reactions Enable a High‐Performance Zn–Air Battery

Zhao

Zhu

et al. 2020

Angewandte Chemie

View full text Add to dashboard Cite

The storage of solar energy in battery systems is pivotal for a sustainable society, which faces many challenges. Herein, a Zn–air battery is constructed with two cathodes of poly(1,4‐di(2‐thienyl))benzene (PDTB) and TiO2 grown on carbon papers to sandwich a Zn anode. The PDTB cathode is illuminated in a discharging process, in which photoelectrons are excited into the conduction band of PDTB to promote oxygen reduction reaction (ORR) and raise the output voltage. In a reverse process, holes in the valence band of the illuminated TiO2 cathode are driven for the oxygen evolution reaction (OER) by an applied voltage. A record‐high discharge voltage of 1.90 V and an unprecedented low charge voltage of 0.59 V are achieved in the photo‐involved Zn–air battery, regardless of the equilibrium voltage. This work offers an innovative pathway for photo‐energy utilization in rechargeable batteries.

show abstract

Tactile UV‐ and Solar‐Light Multi‐Sensing Rechargeable Batteries with Smart Self‐Conditioned Charge and Discharge

Cited by 14 publications

References 37 publications

Harvesting Air and Light Energy via “All‐in‐One” Polymer Cathodes for High‐Capacity, Self‐Chargeable, and Multimode‐Switching Zinc Batteries

Harvesting Air and Light Energy via “All‐in‐One” Polymer Cathodes for High‐Capacity, Self‐Chargeable, and Multimode‐Switching Zinc Batteries

Surface plasmon mediates the visible light–responsive lithium–oxygen battery with Au nanoparticles on defective carbon nitride

Photo‐excited Oxygen Reduction and Oxygen Evolution Reactions Enable a High‐Performance Zn–Air Battery

Contact Info

Product

Resources

About