An Amperometric Type NO2 Sensor Utilizing La0.7Sr0.3MnO3-δ-NiO Composite Sensing Electrode

L. Dai, Tengteng Zhao, Chaoyu Wang, W. Meng, Yongguang Liu, Yuehuan Li, Ling Wang
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Abstract

NO2 is an important pollutant of automobile engines and industrial fuels, making it important to quantitatively monitor and control. An amperometric-type NO2 gas sensor was fabricated using yttria-stabilized zirconia (YSZ) electrolyte with a bi-layered structure and La0.7Sr0.3MnO3-δ-xNiO (LSMO-xNiO, x=0-0.75) composite sensing electrode (SE) prepared by impregnation method in combination with self-demixing. The samples were characterized using SEM, XRD, and XPS, and their performance as sensors was tested. LSMO-xNiO composite SE particles were formed by de-mixing in the process of treating the precursor at high temperatures and are uniformly dispersed in the YSZ porous backbone. With the increase of NiO content, the SE particles become significantly large. At 450-600°C, the response currents at a fixed potential have a linear relationship with the NO2 concentrations at 25-700 ppm. Combining stability and sensitivity, the voltage was fixed to -0.25V. The introduction of NiO into the LSMO sensing electrode effectively improves the performance of the sensor. The sensor based on LSMO-0.5NiO has the highest sensitivity (0.0405 µA/ppm) at 550°C. Simultaneously, the sensor exhibits good anti-interference ability for CH4, CO2, O2, and NO, but has obvious cross-sensitivity to H2 and NH3. In addition, the response current of the sensor change with the increase of RH.
利用 La0.7Sr0.3MnO3-δ-NiO 复合传感电极的安培计型二氧化氮传感器
二氧化氮是汽车发动机和工业燃料的重要污染物,因此对其进行定量监测和控制非常重要。利用双层结构的钇稳定氧化锆(YSZ)电解质和通过浸渍法结合自混合法制备的 La0.7Sr0.3MnO3-δ-xNiO (LSMO-xNiO,x=0-0.75)复合传感电极(SE),制备了一种安培计型二氧化氮气体传感器。使用 SEM、XRD 和 XPS 对样品进行了表征,并测试了它们作为传感器的性能。在高温处理前驱体的过程中,LSMO-xNiO 复合 SE 粒子通过去混合形成,并均匀地分散在 YSZ 多孔骨架中。随着 NiO 含量的增加,SE 颗粒明显变大。在 450-600°C 时,固定电位下的响应电流与 25-700 ppm 的二氧化氮浓度呈线性关系。结合稳定性和灵敏度,电压被固定为 -0.25V。在 LSMO 传感电极中引入氧化镍可有效提高传感器的性能。基于 LSMO-0.5NiO 的传感器在 550°C 时具有最高的灵敏度(0.0405 µA/ppm)。同时,该传感器对 CH4、CO2、O2 和 NO 具有良好的抗干扰能力,但对 H2 和 NH3 有明显的交叉敏感性。此外,传感器的响应电流会随着相对湿度的增加而变化。
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