Jong Hyun Lee, Se Hwang Kang, Gi Hyun Park, Min Young Kim, Sanghyun Ji, Ha Eun Choa, Gi Hyeon Han, Jeong Yun Hwang, Seung Yong Lee, Kyu Hyoung Lee
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引用次数: 0
摘要
在这项研究中,我们证明了通过在镍位点引入取代性铁,典型的非活性 NiWO4(一种强相关电子系统(SCES))中出现了二氧化氮气体传感功能。NiWO4 通常在 Ni 原子间表现出很强的库仑斥力,从而导致超过 3.0 eV 的大带隙和绝缘行为。当考虑对阳离子进行 Hubbard U 修正时,这种相关行为明显反映在带隙的显著增加上,使理论值更接近观测值。单相 Fe0.5Ni0.5WO4 显示出[NiO6]对称振动模式的显著转变和磁化率的增加。此外,理论计算证实了宽带隙的保留,Fe 和 O 电平在带隙内产生。这些发现表明,位于镍位点的铁元素调节了 NiWO4 SCES 绝缘体中的库仑斥力。与本征 NiWO4 较差的气体传感性能不同,Fe0.5Ni0.5WO4 在 200°C 时比其他气体表现出显著的 NO2 响应(Rg/Ra),达到 11,检测限(LOD)为 46.4 ppb。这项研究通过在阳离子位点引入掺杂水平,为在具有较大带隙的强相关电子绝缘体中实现气体传感性能提供了一条途径。
Emerging NO2 gas sensing on substitutionally doped Fe on NiWO4 SCES insulators.
In this study, we demonstrate the emergence of NO2 gas sensing capabilities in the typically non-active NiWO4, a strongly correlated electron system (SCES), by introducing substitutional Fe at the Ni site. NiWO4 typically exhibits strong Coulombic repulsion between Ni atoms, resulting in a large band gap of over 3.0 eV and insulating behavior. This correlated behavior is clearly reflected in the significant increase of band gap when considering the Hubbard U correction for the cations, bringing the theoretical value closer to the observed value. The single-phase Fe0.5Ni0.5WO4 displays a notable shift in the [NiO6] symmetric vibration mode and an increase in magnetization. Additionally, theoretical calculations confirm the preservation of the wide band gap, with the Fe and O levels generated within the band gap. These findings indicate that Fe located in the Ni sites modulate Coulombic repulsion in NiWO4 SCES insulators. Unlike the poor gas-sensing performance of intrinsic NiWO4, Fe0.5Ni0.5WO4 exhibits a significant NO2 response (Rg/Ra) of 11 at 200°C than other gases and a limit of detection (LOD) of 46.4 ppb. This study provides a pathway for realizing gas-sensing performance in strongly correlated electron insulators with large band gaps through the introduction of dopant levels at the cation sites.
期刊介绍:
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