Abstract
Electrochromic materials are vital to the development of dual-band smart windows, which enable the individual control of visible and near-infrared (NIR) light transmittance. In this paper, we propose a novel single-component MoO3−x nanowire fabricated using a simplified preparation method via a fluoride-assisted route. The incorporation of oxygen vacancies into MoO3−x nanowire in the presence of fluoride anions has not been attempted before. Spectroscopic measurements confirm enhanced ion mobility in the MoO3−x conduction band through the Mo6+ substitution of Mo5+ cations as the origin of localized surface plasmon resonance (LSPR). Oxygen vacancies greatly improve Li+ diffusion in the MoO3−x host while providing near-infrared selective modulation due to tunable LSPR absorbance in the NIR region. The MoO3−x nanowire demonstrates excellent dual-band electrochromic performance in terms of switching speed (12.4 s and 5.4 s for coloration and bleaching between 1.0 V and 3.5 V), coloration efficiency (232.8 cm2·C−1 at 1080 nm and 211.7 cm2·C−1 at 450 nm), and electrochemical stability (91.8% at 1080 nm after 1,000 cycles). This suggests that MoO3−x nanowire with oxygen vacancy is a promising new electrochromic material for dual-band smart windows.
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