Quan Wenjing, Shi Jia, Zeng Min, Lv Wen, Chen Xiyu, Fan Chao, Zhang Yongwei, Liu Zhou, Huang Xiaolu, Yang Jianhua, Hu Nantao, Wang Tao, Yang Zhi
National Key Laboratory of Advanced Micro and Nano Manufacture Technology, Shanghai Jiao Tong University, Shanghai, 200240, People's Republic of China.
Department of Micro/Nano Electronics, School of Electronic Information and Electrical Engineering, Shanghai Jiao Tong University, Shanghai, 200240, People's Republic of China.
Nanomicro Lett. 2024 Aug 27;16(1):277. doi: 10.1007/s40820-024-01484-4.
Significant challenges are posed by the limitations of gas sensing mechanisms for trace-level detection of ammonia (NH). In this study, we propose to exploit single-atom catalytic activation and targeted adsorption properties to achieve highly sensitive and selective NH gas detection. Specifically, Ni single-atom active sites based on N, C coordination (Ni-N-C) were interfacially confined on the surface of two-dimensional (2D) MXene nanosheets (Ni-N-C/TiCT), and a fully flexible gas sensor (MNPE-Ni-N-C/TiCT) was integrated. The sensor demonstrates a remarkable response value to 5 ppm NH (27.3%), excellent selectivity for NH, and a low theoretical detection limit of 12.1 ppb. Simulation analysis by density functional calculation reveals that the Ni single-atom center with N, C coordination exhibits specific targeted adsorption properties for NH. Additionally, its catalytic activation effect effectively reduces the Gibbs free energy of the sensing elemental reaction, while its electronic structure promotes the spill-over effect of reactive oxygen species at the gas-solid interface. The sensor has a dual-channel sensing mechanism of both chemical and electronic sensitization, which facilitates efficient electron transfer to the 2D MXene conductive network, resulting in the formation of the NH gas molecule sensing signal. Furthermore, the passivation of MXene edge defects by a conjugated hydrogen bond network enhances the long-term stability of MXene-based electrodes under high humidity conditions. This work achieves highly sensitive room-temperature NH gas detection based on the catalytic mechanism of Ni single-atom active center with N, C coordination, which provides a novel gas sensing mechanism for room-temperature trace gas detection research.
用于痕量氨(NH₃)检测的气敏机制存在局限性,带来了重大挑战。在本研究中,我们提议利用单原子催化活化和靶向吸附特性来实现对NH₃气体的高灵敏度和高选择性检测。具体而言,基于N、C配位的Ni单原子活性位点(Ni-N-C)被界面限制在二维(2D)MXene纳米片(Ni-N-C/Ti₃C₂Tₓ)表面,并集成了一个完全柔性的气体传感器(MNPE-Ni-N-C/Ti₃C₂Tₓ)。该传感器对5 ppm NH₃表现出显著的响应值(27.3%),对NH₃具有优异的选择性,理论检测下限低至12.1 ppb。密度泛函计算的模拟分析表明,具有N、C配位的Ni单原子中心对NH₃表现出特定的靶向吸附特性。此外,其催化活化作用有效降低了传感元素反应的吉布斯自由能,同时其电子结构促进了气固界面处活性氧物种的溢出效应。该传感器具有化学敏化和电子敏化的双通道传感机制,有利于高效电子转移到2D MXene导电网络,从而形成NH₃气体分子传感信号。此外,共轭氢键网络对MXene边缘缺陷的钝化增强了基于MXene的电极在高湿度条件下的长期稳定性。这项工作基于具有N、C配位的Ni单原子活性中心的催化机制实现了高灵敏度的室温NH₃气体检测,为室温痕量气体检测研究提供了一种新颖的气敏机制。
