2018年8月15日 · XRD was applied to analyze the phase composition and crystal structure features of the Cs x WO 3 particles obtained by heating for 4 h at different temperatures (220–280 °C). All diffraction peaks could be well indexed to hexagonal caesium tungsten bronze (JCPDS no. 83-1334) (Fig. 1), and no impurity peaks were identified.

The UV-Visible and near-infrared (UV-Vis-NIR) of CsxWO3 products were studied. The CsxWO3 and its nanocomposites characterised by X-ray diffraction (XRD), scanning electr...

The detected XRD peaks indicate the nanorods formation with the main phase (200) which is in agreement with the main characteristic peaks of Cs-doped Tungsten bronze (Cs-doped WO 3 ) reported in...

In this study, we demonstrate sustainable and green nanotechnology for room-temperature synthesis of HxWO3 (0 < x < 0.5) via a novel reaction pathway induced by mechanical energy.

2016年4月1日 · In this work, full-spectrum-response photocatalytic activities covering UV, visible and near infrared regions on degradation of methylene blue have been realized firstly on single matter of the mixed valence Cs0.32 WO 3 nanorod.

通过动态光散射（DLS）、透射电子显微镜（TEM）、X射线衍射（XRD）和紫外-可见光谱（UV-Vis）技术，系统地研究了金纳米棒含量对复合材料晶体尺寸、粒径、形状和光学性质的影响。

Cs x WO 3 is a great candidate for application in solar filters based on its high transmittance in the visible region and excellent shielding performance in the near-infrared (NIR) region. However, the relationship between NIR absorption performance and different shaped Cs x WO 3 particles has been rarely reported.

2024年6月5日 · This research aims to enhance the near-infrared (NIR) shielding ability of cesium tungsten bronze (CsWO 3) by increasing the spectral absorption in this region through the incorporation of gold nanorods (Au NR). Two approaches were used to prepare the composite materials: physical mixing and solvothermal process.

The FCDs were further integrated with near-infrared (NIR)-responsive cesium tungsten oxide (CsWO3) by utilizing catechol moieties on the FCD surface for photothermal-based antibacterial activity.

本研究旨在通过掺入金纳米棒 (AuNR) 来增加该区域的光谱吸收，从而增强铯钨青铜 (CsWO3) 的近红外 (NIR) 屏蔽能力。 采用两种方法制备复合材料：物理混合和溶剂热法。