Tunable Sensor(可调传感器)研究综述
Tunable Sensor 可调传感器 - The idea is to utilize a set of radical-sensitive molecules as tunable sensors, followed by insight into the studied radical species based on the observed reactivity/selectivity. [1] The study highlights the suitability of LIPSS in applications requiring efficient energy transfer, enhanced photocatalytic action, and tunable sensors. [2] Materials with adaptable properties could impact optoelectronics (tunable sensors or filters) and chemical reactivity (triggered reactivity). [3] In this paper, a plasmonic perfect absorber based on metal-insulator-graphene-metal structure is proposed as a tunable sensor. [4] The proposed absorber, with polarization insensitivity and incidence angle of 30° for both TE and TM polarizations, may have potential applications in tunable sensors, modulators, and imaging. [5] With optimized geometry, the system can work as a tunable sensor with a wide UV wavelength range λ∼ 150–300 nm. [6] The absorber can be scalable to the infrared and visible frequencies and demonstrates promising application on tunable sensors, filters, and photovoltaic devices. [7] The rasorber could be scalable to the infrared and visible frequencies, and could be used as tunable sensors, radome, cloaking, filters and photovoltaic devices. [8] The proposed static and dynamic piezopotential tuned MoS2 FET is easy to extend to devices based on other materials, which is highly desired in tunable sensory systems, active flexible electronics, and human−machine interface. [9] For an adaptive spectral imaging system with a tunable sensor, we would be able to optimize detection for a specific target and save data handling costs associated with transmitting, storing, and disseminating the data for information extraction. [10] Such a device could be used as tunable sensors, filters, detector or other graphene-based photonic devices. [11] This work indicates that our device has potential applications with respect to tunable sensors and smart absorbers. [12] The proposed static and dynamic piezopotential tuned MoS2 FET is easy to extend to devices based on other materials, which is highly desired in tunable sensory systems, active flexible electronics, and human-machine interface. [13] The tunable sensor is based on a perfect absorber, and an indium tin oxide (ITO) layer has been utilized as an active metasurface to improve sensor performance. [14] We believe that our devices may pave the way for the design of tunable sensors in terahertz and other frequency bands. [15]这个想法是利用一组自由基敏感分子作为可调传感器,然后根据观察到的反应性/选择性深入了解研究的自由基种类。 [1] 该研究强调了 LIPSS 在需要高效能量转移、增强光催化作用和可调谐传感器的应用中的适用性。 [2] 具有适应性的材料可能会影响光电子学(可调谐传感器或滤波器)和化学反应性(触发反应性)。 [3] 在本文中,提出了一种基于金属-绝缘体-石墨烯-金属结构的等离子体完美吸收体作为可调谐传感器。 [4] 所提出的吸收器对 TE 和 TM 偏振具有偏振不敏感性和 30° 的入射角,可能在可调谐传感器、调制器和成像中具有潜在的应用。 [5] 通过优化的几何结构,该系统可以作为具有宽紫外波长范围 λ∼150–300 nm 的可调传感器工作。 [6] 该吸收器可以扩展到红外和可见光频率,并在可调谐传感器、滤波器和光伏器件上展示了广阔的应用前景。 [7] 吸收器可以扩展到红外和可见频率,并且可以用作可调谐传感器、天线罩、隐形、过滤器和光伏设备。 [8] 所提出的静态和动态压电调谐 MoS2 FET 很容易扩展到基于其他材料的设备,这在可调谐传感系统、有源柔性电子设备和人机界面中是非常需要的。 [9] 对于具有可调传感器的自适应光谱成像系统,我们将能够优化对特定目标的检测,并节省与传输、存储和传播用于信息提取的数据相关的数据处理成本。 [10] 这种器件可以用作可调谐传感器、滤波器、检测器或其他基于石墨烯的光子器件。 [11] 这项工作表明我们的设备在可调传感器和智能吸收器方面具有潜在应用。 [12] 所提出的静态和动态压电调谐 MoS2 FET 很容易扩展到基于其他材料的设备,这在可调谐传感系统、有源柔性电子设备和人机界面中是非常需要的。 [13] 可调谐传感器基于完美的吸收体,氧化铟锡 (ITO) 层已被用作有源超表面以提高传感器性能。 [14] 我们相信,我们的设备可能为太赫兹和其他频段的可调谐传感器的设计铺平道路。 [15]