Low-Concentration Electrolytes toward High-Performance Aqueous Ammonium-Ion Electrochromic Devices

Low-Concentration Electrolytes toward High-Performance Aqueous Ammonium-Ion Electrochromic Devices

Ammonium-ion electrochromic devices (AECDs) have emerged as a promising candidate for next-generation intelligent electronics with visible working states. However, developing electrodes exhibiting remarkable electrochromic performance and exceptional long-term cycling stability within suitable ammon...

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Bibliographic Details
Main Author: Chen Li (54018) (author)
Other Authors: Jiguang Chen (2902420) (author), Lei Liu (5074) (author), Boshan Sun (13521556) (author), Xiaoran Liu (1553812) (author), Yanqing Gao (2590384) (author), Qirong Liu (5562065) (author), Jing Miao (267400) (author)
Published: 2025
Subjects:
Medicine
Biotechnology
Space Science
Biological Sciences not elsewhere classified
Chemical Sciences not elsewhere classified
work provides insights
visible working states
term cycling stability
molecular dynamics simulations
various aqueous electrolytes
93 </ sub
4 </ sub
2 </ sub
18 </ sub
16 </ sub
3000 cycles ).
ion hydrogel electrolytes
remarkable electrochromic performance
generation intelligent electronics
ion electrochromic devices
performance aqueous ammonium
ion electrochemical devices
ion electrolytes
electrochromic performances
intelligent ammonium
5000 cycles
performance aecds
systematically investigated
real time
quantitative relationship
prussian blue
promising candidate
optical characteristics
operational state
next generation
infancy stage
experimental exploration
electrochemical reactions
different concentrations
becomes feasible
630 nm
3 %.
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Summary:Ammonium-ion electrochromic devices (AECDs) have emerged as a promising candidate for next-generation intelligent electronics with visible working states. However, developing electrodes exhibiting remarkable electrochromic performance and exceptional long-term cycling stability within suitable ammonium-ion electrolytes is highly desirable yet challenging. Herein, the electrochemical and electrochromic performances of Prussian blue (PB) electrodes were systematically investigated in various aqueous electrolytes and different concentrations of (NH<sub>4</sub>)<sub>2</sub>SO<sub>4</sub> electrolyte. According to experimental exploration and molecular dynamics simulations, a low-concentration electrolyte is conducive to high-performance AECDs. A 0.25 M (NH<sub>4</sub>)<sub>2</sub>SO<sub>4</sub> solution was identified as yielding optimal fast diffusion kinetics, remarkable electrochromic performance of PB electrodes, and excellent long-term cycling stability over 5000 cycles with a retention of 82.3%. Furthermore, by coupling it with a transparent electrochromic negative electrode composed of Nb<sub>18</sub>W<sub>16</sub>O<sub>93</sub> (NbWO) and ammonium-ion hydrogel electrolytes, a quasi-solid-state AECD is assembled. It demonstrates remarkable optical modulation (61.1% at 630 nm) and long-term cycling stability (more than 3000 cycles). Significantly, based on the discovery of the quantitative relationship between the optical characteristics and electrochemical reactions in devices, it becomes feasible to assess the operational state of the AECD in real time. Considering that the development of AECDs is still in the infancy stage, this work provides insights and perspectives for the next generation of intelligent ammonium-ion electrochemical devices.

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