金属纳米颗粒:氧化镍、氧化亚铜和铁酸锡的室温湿度传感研究

IF 0.8 Q4 MATERIALS SCIENCE, BIOMATERIALS Nano Life Pub Date : 2022-03-09 DOI:10.1142/s1793984422500015
Swati Singh, P. Chaudhary, Sunanda Singh, Vandana Verma, R. Srivastava, R. K. Tripathi, Kaman Singh, B. Yadav
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引用次数: 1

摘要

本文介绍了合成不同金属氧化物纳米颗粒的简单方法及其在室温湿度传感应用中的比较研究。这些金属氧化物纳米颗粒的合成是通过氧化镍和铁氧体锡的共沉淀法和氧化亚铜的水热法进行的。SEM和EDX揭示了合成的金属氧化物的多孔形态和确定的组成。FTIR检测到–OH等官能团的存在,并证实了锡铁氧体中的反向脊柱结构。通过UV光谱测定光学带隙:NiO为3.86[公式:见正文]eV,Cu2O为4.13[公式:见图正文]eV,SnFe2O4为4.07[公式:详见正文]eV。XRD给出了关于铁氧体锡2.42[公式:见正文]nm、氧化亚铜12.88[公式:见图正文]nm和氧化镍22.51[公式:参见正文]nm的平均晶粒尺寸的信息。随着尺寸达到纳米范围,表面积增加,这是湿度传感的良好指示。材料的湿度传感是通过电模式检测的。通过旋涂机制备沉积的薄膜,并且观察到的这些膜的灵敏度对于NiO为0.72[公式:参见文本]M[公式:见文本]/%RH,对于Cu2O为1.59[公式:见图文本]/%RH,对于SnFe2O4为2.07[公式:参阅文本]M]公式:见文本]/%RH。几周后重复实验,发现样品的老化影响可以忽略不计,这使得传感器稳定。
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Investigation on Metal Nanoparticles: Nickel Oxide, Cuprous Oxide and Tin Ferrite with Their Humidity Sensing at Room Temperature
This paper deals with the facile approach to the synthesis of different metal oxide nanoparticles and their comparative study for humidity sensing application at room temperature. The synthesis of these metal oxide nanoparticles is through co-precipitation method for nickel oxide and tin ferrite and hydrothermal route for cuprous oxide. The SEM and EDX reveal the porous morphology and confirmed composition of the synthesized metal oxides. FTIR detects the presence of functional groups like –OH and confirms the inverse spinal structure in tin ferrite. The optical band gap was determined by UV spectroscopy: 3.86[Formula: see text]eV for NiO, 4.13[Formula: see text]eV for Cu2O, and 4.07[Formula: see text]eV for SnFe2O4. XRD gives the information about the average crystallite size for tin ferrite 2.42[Formula: see text]nm, cuprous oxide 12.88[Formula: see text]nm and nickel oxide 22.51[Formula: see text]nm as the size comes to nano range the surface area increases, which is a good indication for humidity sensing. The humidity sensing of materials was detected by electrical modes. The deposited thin films were prepared by spin coater and observed sensitivity of these films was 0.72[Formula: see text]M[Formula: see text]/%RH for NiO, 1.59[Formula: see text]M[Formula: see text]/%RH for Cu2O, and 2.07[Formula: see text]M[Formula: see text]/%RH for SnFe2O4. The experiments were repeated after few weeks and the aging effects of samples were found negligible which makes the sensor stable.
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来源期刊
Nano Life
Nano Life MATERIALS SCIENCE, BIOMATERIALS-
CiteScore
0.70
自引率
12.50%
发文量
14
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