电化学应用显示掺杂 TiO2 的 ZnS 纳米复合材料具有更强的光催化性能。

IF 4.6 Q2 MATERIALS SCIENCE, BIOMATERIALS ACS Applied Bio Materials Pub Date : 2024-10-30 DOI:10.1002/jemt.24722
S Synthiya, T Thilagavathi, R Uthrakumar, R Renuka, C Inmozhi, K Kaviyarasu
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引用次数: 0

摘要

二氧化钛(TiO2)纳米粒子是在常温下通过水热法制备的。根据 XRD 分析,计算出纯 TiO2 纳米粒子和掺杂 ZnS 纳米粒子的平均结晶尺寸分别为 58 纳米和 54 纳米。在 25.4° 的角度下,在 TiO2 的(101)平面上观察到的突出峰得到了证实。从峰值集合中可以看出,形成的二氧化钛具有锐钛型四方晶体结构。从 W-H 图中可以看出,TiO2 纳米粒子的应变为 -6.4541 × 10-4,晶粒大小为 33 nm。而掺杂 ZnS 纳米粒子的应变值为 1.9448 × 10-4,晶粒大小为 47 nm。在我们的研究中,我们发现掺杂纳米粒子的平均粒度为 134 nm,而纯纳米粒子的平均粒度为 146 nm。掺杂会减小纳米材料的尺寸,这意味着二氧化钛分子会在其表面形成纳米团簇,从而导致纯纳米粒子的晶粒尺寸大于掺杂纳米粒子。利用傅立叶变换红外光谱对合成纳米材料中的各种官能团及其相关键进行了研究。TiOTi 键受到强烈的伸缩振动,这可以从 450 cm-1 到 800 cm-1 的吸收峰中得到证实。纯 TiO2 和掺杂 ZnS 的 TiO2(含 ZnS 纳米复合材料)的 PL 光谱在紫外区发出波长为 362 和 379 nm 的紫外光。纯样品和掺杂样品的光带隙能量分别为 ~3.04 和 ~3.8 eV,对应锐钛矿相,在陶氏图中接近 ~3.18 eV。由于掺杂 TiO2 的 ZnS 异质结会将光激发空穴移向界面,而电子则移向体,这导致光激发空穴移向界面。为了计算合成材料的比电容,纯 ZnS 和掺杂 ZnS 材料的循环伏安比电容值分别为 144.91 F/g 和 120.11 F/g。使用的催化剂除了纯 TiO2 纳米粒子外,还有掺杂了 TiO2 的 ZnS 纳米复合材料。用紫外可见分光光度计每隔 20 分钟监测一次日光照射后 80 分钟内染料的降解情况。掺杂 TiO2 的 ZnS 纳米粒子比纯 TiO2 纳米粒子的效率高 87.8%。掺杂 TiO2 纳米复合材料的降解率为 87.8%,而纯 TiO2 的降解率约为 54%,这表明掺杂剂增强了光催化作用。
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Electrochemical Applications Reveal Enhanced Photocatalytic Performance of TiO2-Doped ZnS Nanocomposites.

The titanium dioxide (TiO2) nanoparticles were prepared by hydrothermal methods at ambient temperature. Based on XRD analysis, the average crystallite size of pure TiO2 nanoparticles and those doped with ZnS was calculated to be 58 and 54 nm, respectively. At an angle of 25.4°, the prominent peak observed at the (101) plane of TiO2 was confirmed. As can be seen from the collection of peaks, the TiO2 formed has an anatase-type tetragonal crystal structure. A strain of -6.4541 × 10-4 and a grain size of 33 nm can be seen in the W-H plot for TiO2 nanoparticles. For doped ZnS nanoparticles, on the other hand, the values are 1.9448 × 10-4 and 47 nm. In our study, we found that doped nanoparticles were average grain size 134 nm, while pure nanoparticles were average grain size 146 nm. Doping reduces the size of the nanomaterial, which means that the TiO2 molecules form nanoclusters on their surfaces, which can lead to a larger grain size for a pure nanoparticle than for a doped nanoparticle. A wide range of functional groups and their associated bonds were investigated using FTIR spectra in synthesized nanomaterials. TiOTi bonds are subjected to a strong stretching vibration, which is confirmed by the absorption peaks from 450 cm-1 to 800 cm-1. The PL spectra for pure TiO2- and ZnS-doped TiO2 containing nanocomposites of ZnS emit ultraviolet light at wavelengths of 362 and 379 nm in the UV region. Pure and doped samples with optical bandgap energies of ~3.04 and ~3.8 eV corresponding to anatase phases were near ~3.18 eV in Tauc plots. Since the TiO2-doped ZnS heterojunction migrates photoexcited holes toward the interface, while electrons migrate toward the bulk, this results in photoexcited holes migrating toward the interface. To calculate the specific capacitance of the synthesized materials, cyclic voltammetry with pure ZnS and those with ZnS-doped had specific capacitance values of 144.91 F/g and 120.11 F/g, respectively. The catalysts used were ZnS nanocomposite doped with TiO2 in addition to pure TiO2 nanoparticles. The degradation of dye within 80 min after sunlight exposure was monitored with a UV-Vis spectrophotometer at 20-min intervals. ZnS nanoparticles doped with TiO2 display 87.8% greater efficiency than pure nanoparticles. Doped TiO2 nanocomposite degrades at an 87.8% rate, whereas pure TiO2 degrades at ~54%, indicating that the dopants enhance photocatalysis.

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