研究了 BaTiO3 纳米粒子作为光催化剂在合成和表征新型水果染料中的作用。

IF 4.6 Q2 MATERIALS SCIENCE, BIOMATERIALS
N N Shafeera, D Saravanakkumar, K Mohamed Rafi, A Ayeshamariam, K Kaviyarasu
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引用次数: 0

摘要

本研究利用 BaTiO3 纳米粒子(NPs)在紫外线(UV)光源下对从新型水果中提取的天然染料进行了光催化活性研究。这种植物化学提取物中存在的高浓度基本酚类物质与布料纤维叠加在一起,会产生强烈的染色并降解成另一种形式的有毒物质,这种有毒物质被排除在许多纺织行业的多彩废水之外,而这些废水没有经过回收利用,研究人员使用光降解和光致发光技术对这种染料颜料进行了去除。采用软化学根改良溶热合成组合方法制备了有权利的纳米颗粒(NPs),并对其进行了热处理,例如在 100°C 至 250°C 的不同温度下进行退火处理。在表征方面,首先进行了结构和形貌研究,利用粉末 X 射线衍射技术(PXRD)获得了高结晶取向峰数据,并利用场发射扫描电子显微镜(FESEM)技术获得了包括尺寸、形状和质量分布在内的表面形貌,它们分别纯粹属于金红石四方结构晶系以及圆形和非圆形片状粗糙表面形貌材料。通过对晶体学数据进行威廉森-霍尔(W-H plot)分析,确定 BaTiO3 NPs 的晶格解离常数 "ε "值为 ~2.71 × 10-3。在紫外可见光谱的研究结果中,由于 BaTiO3 纳米片/纳米盘具有极强的量子约束,因此光能带隙的范围估计为 1.98 至 2.67 eV(约 2.在紫外-可见光照射下,激子形成、超氧离子和羟基自由基的生成表现优异,从而有效降解了典型的新型水果有机染料。在室温和低温下观察到的 BaTiO3 纳米薄片的光致发光光谱显示,由于晶体缺陷(如 Ba 空位的出现导致 p 型导电性的开始)和自由激子发射的产生,纳米薄片显示出蓝色发射,这揭示了纳米薄片的直接带隙转变性质。研究亮点:根据我们的研究结果,89.71%的天然茜草孜然在光催化反应中被降解。光催化破坏是天然染料在太阳光下被破坏的一种合理机制。这些活性自由基之间的反应导致了高效率的光降解,而且衰减时间很短。除了水处理和环境清洁应用外,这种光催化剂的优异性能也使其在其他应用领域大有可为。因此,合成的 BaTiO3 纳米片在开发纺织品染料回收方法方面取得了重大进展。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
The role of BaTiO3 nanoparticles as photocatalysts in the synthesis and characterization of novel fruit dyes is investigated.

In the present work, the photocatalytic activity against the natural dye extracted from the novel fruits has been studied by the BaTiO3 nanoparticles (NPs) under a ultra-violet (UV) light source. The large concentrations of an essential phenolic agent present in this phytochemical extract superimposed with cloths fibers make strong stain and degrade into another form of toxic, which is excluded from the many textiles industries as the colorful waste waters without recycling and removal of that dye pigments have been investigated using both photodegradation and photoluminescence techniques. The entitled nanoparticles (NPs) were prepared using the soft chemical root-modified solvothermal synthesis combo method and exposure to heat treatment such that the annealing process has been done for different temperatures ranging from 100°C to 250°C. As for as concern the characterization, as a start, structural and morphology studies have been reported here that highly crystalline oriented peaks data using powder x-ray diffraction techniques (PXRD) as well as the surface morphology including the size, shape, and mass distribution using the field emission scanning electron microscopy (FESEM) techniques, which purely belong to rutile tetragonal structure of the crystal system and circular and noncircular flakes like rough surface morphology materials respectively. The lattice dissociation constant 'ε' value of the BaTiO3 NPs has determined to be ~2.71 × 10-3 using the Williamson-Hall (W-H plot) analysis of crystallographic data. In the UV visible spectroscopy findings, since the extreme quantum confinement of BaTiO3 nanoflakes/nanodisc, the optical energy bandgap has been estimated to be a range of 1.98 to 2.67 eV (~2.48 eV) found from the Tauc plot analysis, which contributes to the significantly owing to the enhanced photocatalytic efficiency with excellent performance along exciton formation, superoxide ions, and hydroxyl free radicals generations under UV-vis light irradiation resulting in efficient degradation of typical novel fruit organic dye. Photoluminescence spectra observed at room temperature and low temperature have been observed for the BaTiO3 nanoflakes, which exhibit the blue emission due to the crystalline defects such as the appearance of Ba vacancies leads to the conceivable beginning of p-type conductivity and the origination of free exciton emission reveals the direct bandgap transition nature of nanoflakes. RESEARCH HIGHLIGHTS: According to our findings, 89.71% of the natural syzygium cumin is degraded by photocatalysis reaction. As a plausible mechanism for the destruction of natural dyes under solar light, photocatalytic destruction has been proposed. The reaction between these reactive free radical species leads to high efficiency photodegradation with a short decay time. In addition to water treatment and environmental cleaning applications, the excellent performance of this photocatalyst makes it a promising candidate for other applications. Hence, the synthesized BaTiO3 nanoflakes showcase a highly significant advancement towards the development of a textiles dye recycling method.

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来源期刊
ACS Applied Bio Materials
ACS Applied Bio Materials Chemistry-Chemistry (all)
CiteScore
9.40
自引率
2.10%
发文量
464
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