AI Article Synopsis
- Complementary electrochromic devices (ECDs) are used in smart windows but struggle with stability due to issues like ion-trapping and charge mismatches between their electrodes.
- This study presents a new design with a partially covered nickel oxide (NiO) and platinum (Pt) counter electrode, which stabilizes performance and addresses charge imbalance.
- The improved device shows impressive performance metrics, including 68.2% optical modulation, rapid color change times, and the ability to endure 10,000 cycles, making it a promising solution for practical applications.
Article Abstract
Complementary electrochromic devices (ECDs) composed of WO and NiO electrodes have wide applications in smart windows. However, they have poor cycling stability due to ion-trapping and charge mismatch between electrodes, which limits their practical application. In this work, we introduce a partially covered counter electrode (CE) composed of NiO and Pt to achieve good stability and overcome the charge mismatch based on our structure of electrochromic electrode/Redox/catalytic counter electrode (ECM/Redox/CCE). The device is assembled using a NiO-Pt counter electrode with WO as the working electrode, and PC/LiClO containing a tetramethylthiourea/tetramethylformaminium disulfide (TMTU/TMFDS) redox couple as the electrolyte. The partially covered NiO-Pt CE-based ECD exhibits excellent EC performance, including a large optical modulation of 68.2% at 603 nm, rapid switching times of 5.3 s (coloring) and 12.8 s (bleaching), and a high coloration efficiency of 89.6 cm·C. In addition, the ECD achieves a good stability of 10,000 cycles, which is promising for practical application. These findings suggest that the structure of ECC/Redox/CCE could overcome the charge mismatch problem. Moreover, Pt could enhance the Redox couple's electrochemical activity for achieving high stability. This research provides a promising approach for the design of long-term stable complementary electrochromic devices.
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| http://www.ncbi.nlm.nih.gov/pmc/articles/PMC10301611 | PMC |
| http://dx.doi.org/10.3390/membranes13060601 | DOI Listing |
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