Vapor Sensor(蒸汽传感器)研究综述
Vapor Sensor 蒸汽传感器 - However, the development of vapor sensors is very slow. [1] Phosphorene received considerable attention as gas/vapor sensors owing to its gas/vapor interaction and its chemi-resistive properties. [2] 5 mL of thawed, previously banked plasma samples from 93 total individuals were analyzed using a 10-channel nanoelectronic olfaction (“e-nose”) system based on single-stranded DNA-decorated single-walled carbon nanotube (DNA-NT) vapor sensors. [3] V2O5 nanowires based vapor sensors were fabricated using calcinated electrospun nanofibers. [4] Calix[4]arenes bearing phosphate and crown ether groups are shown to hold considerable promise as the active layer in volatile organic compound (VOC) vapor sensor. [5] The vapor sensors could detect CHCl3 vapor as low as 50 ppm, and offered a wide vapor concentration range, good restorability and high vapor sensitivity of 0. [6] Accordingly, relying on the strong absorption capability of PFSA, a TENG-based vapor sensor with high sensitivity has been developed for monitoring chemical vapor leakage and humidity change. [7] A vapor sensor was constructed to demonstrate the environmental detection ability of this unique actuator. [8] In this work, we present robust and easy-to-fabricate optical gas and vapor sensors based on optical fiber resonators (OFR) coated with palladium (Pd) thin films, Pd micro-particles and polymer brushes (PB). [9] The strong and rational chemical interactions of molecular and polymeric organic semiconductors (OSCs) make the use of organic field-effect transistors (OFETs) compelling for vapor sensors. [10] The results are consistent with previous studies of vapor sensors that employ carbon black-polymer films as sensing materials. [11] toluene and xylene) using oxide semiconductor-based gas/vapor sensors is highly desirable but limited by the low chemical reactivity of the benzene compounds. [12] Nano- and microscale tetrapodal shaped ZnO particles (T-ZnO) are considered to be truly multi-functional and have a tremendous potential for a large variety of applications ranging from gas/vapor sensors to biomedical implants. [13] This paper endeavors to answer an important question posed during the fabrication of vapor sensors based on multiwall carbon nanotubes (MWCNTs): How do the preparation and measurement conditions influence the sensor response in real-life situations? A satisfactory answer could be given in view of the effects produced by the surface functionalization of MWCNTs and various solvent vapors. [14] Gas/vapor sensors based on photonic band gap-type materials are attractive as they allow a quick optical readout. [15] In this chapter, we describe methods for the scalable production of gFET-based vapor sensors with high sensitivity and efficiency in size, cost, and time. [16] The simple and efficient approach allows large scale preparation of amphiphilic Janus Au NPs at low cost for versatile applications, such as drug delivery, vapor sensors and heterogeneous catalysts. [17]然而,蒸汽传感器的发展非常缓慢。 [1] 由于其气体/蒸汽相互作用和化学电阻特性,磷烯作为气体/蒸汽传感器受到了相当多的关注。 [2] 使用基于单链 DNA 装饰的单壁碳纳米管 (DNA-NT) 蒸汽传感器的 10 通道纳米电子嗅觉 (“e-nose”) 系统分析了来自 93 个个体的 5 mL 解冻的、先前储存的血浆样本. [3] 使用煅烧的电纺纳米纤维制造基于 V2O5 纳米线的蒸汽传感器。 [4] 带有磷酸盐和冠醚基团的杯形 [4] 芳烃作为挥发性有机化合物 (VOC) 蒸汽传感器中的活性层具有相当大的前景。 [5] 蒸汽传感器可检测低至 50ppm 的 CHCl3 蒸汽,并提供宽的蒸汽浓度范围、良好的可恢复性和高达 0 的蒸汽灵敏度。 [6] 因此,依托PFSA强大的吸收能力,开发了一种基于TENG的高灵敏度蒸汽传感器,用于监测化学蒸汽泄漏和湿度变化。 [7] 构建了一个蒸汽传感器来展示这种独特执行器的环境检测能力。 [8] 在这项工作中,我们提出了基于涂有钯 (Pd) 薄膜、Pd 微粒和聚合物刷 (PB) 的光纤谐振器 (OFR) 的坚固且易于制造的光学气体和蒸汽传感器。 [9] 分子和聚合物有机半导体 (OSC) 的强而合理的化学相互作用使得有机场效应晶体管 (OFET) 的使用对蒸汽传感器具有吸引力。 [10] 结果与先前对采用炭黑聚合物薄膜作为传感材料的蒸汽传感器的研究一致。 [11] 甲苯和二甲苯)使用基于氧化物半导体的气体/蒸汽传感器是非常理想的,但受限于苯化合物的低化学反应性。 [12] 纳米和微米级的四足形 ZnO 颗粒 (T-ZnO) 被认为是真正的多功能,并且在从气体/蒸汽传感器到生物医学植入物的各种应用中具有巨大的潜力。 [13] 本文试图回答在基于多壁碳纳米管 (MWCNT) 的蒸汽传感器制造过程中提出的一个重要问题:制备和测量条件如何影响传感器在现实生活中的响应?鉴于多壁碳纳米管的表面功能化和各种溶剂蒸气所产生的效果,可以给出令人满意的答案。 [14] 基于光子带隙型材料的气体/蒸汽传感器很有吸引力,因为它们允许快速光学读数。 [15] 在本章中,我们描述了基于 gFET 的蒸汽传感器的可扩展生产方法,这些传感器在尺寸、成本和时间方面具有高灵敏度和高效率。 [16] 这种简单而有效的方法允许以低成本大规模制备两亲性 Janus Au NPs,用于多种应用,例如药物输送、蒸汽传感器和多相催化剂。 [17]
Organic Vapor Sensor 有机蒸气传感器
An optical organic vapor sensor array based on colorimetric or fluorescence changes quantified by spectroscopy provides an efficient method for realizing rapid identification and detection of organic vapor, but improving the sensitivity of the optical organic vapor sensor is challenging. [1] Organic vapor sensors are used in diverse applications ranging from environmental monitoring to biomedical diagnostics. [2] This work provides a facile but cost-effective way to fabricate ACFs, enabling its industrial-scale application as organic vapor sensor with high stability and satisfied reliability. [3] An artificial organic vapor sensor based on a finite number of 1D nanowires arrays can provide a strategy to allow classification and identification of different analytes with high efficiency, but fabricating a 1D nanowires array is challenging. [4] This work paves a new way for design and development of advanced highly sensitive and fast responsive organic vapor sensors by using an insulating second filler to tune porous conductive structure. [5]基于光谱量化的色度或荧光变化的光学有机蒸气传感器阵列为实现有机蒸气的快速识别和检测提供了一种有效的方法,但提高光学有机蒸气传感器的灵敏度具有挑战性。 [1] 有机蒸气传感器用于从环境监测到生物医学诊断等多种应用。 [2] 这项工作为制造 ACF 提供了一种简便但具有成本效益的方法,使其能够作为具有高稳定性和令人满意的可靠性的有机蒸汽传感器进行工业规模应用。 [3] 基于有限数量的一维纳米线阵列的人造有机蒸气传感器可以提供一种策略,允许高效地分类和识别不同的分析物,但制造一维纳米线阵列具有挑战性。 [4] 这项工作通过使用绝缘的第二填料来调整多孔导电结构,为设计和开发先进的高灵敏度和快速响应的有机蒸汽传感器铺平了新的道路。 [5]
Chemical Vapor Sensor
Based on this configuration, researchers demonstrated a chemical vapor sensor with high sensitivity. [1] In this study, highly sensitive chemical vapor sensors fabricated from fluorinated t. [2] Conductive polymer composites (CPCs) are good candidates as chemical vapor sensors. [3] Humidity and chemical vapor sensors have promising applications in the field of environment protection, human healthcare, and so forth. [4]基于这种配置,研究人员展示了一种具有高灵敏度的化学蒸汽传感器。 [1] 在这项研究中,由氟化 t 制成的高灵敏度化学蒸汽传感器。 [2] 导电聚合物复合材料 (CPC) 是很好的化学蒸汽传感器候选者。 [3] 湿度和化学蒸汽传感器在环境保护、人类保健等领域具有广阔的应用前景。 [4]
Ethanol Vapor Sensor 乙醇蒸汽传感器
In this paper different Indium Tin Oxide (ITO)-based ethanol vapor sensors (fabricated as thin films and nanoparticles) are presented, and their structural and sensing properties are investigated. [1] Moreover, these micro-ring resonators are exemplified into the demonstration of an ethanol vapor sensor, readily achieving detectivities of 0. [2] The present paper reports a highly sensitive room temperature operable ethanol vapor sensor based on the electrical properties of nanostructured Pd-doped SnO2. [3] An ethanol vapor sensor based on a microfiber with a quantum-dot (QD) gel coating is proposed and demonstrated. [4]本文介绍了不同的基于氧化铟锡 (ITO) 的乙醇蒸汽传感器(制成薄膜和纳米颗粒),并研究了它们的结构和传感特性。 [1] 此外,这些微环谐振器以乙醇蒸汽传感器的演示为例,很容易实现 0 的检测率。 [2] 本文报道了一种基于纳米结构 Pd 掺杂 SnO2 电学特性的高灵敏度室温可操作乙醇蒸汽传感器。 [3] 提出并演示了一种基于具有量子点 (QD) 凝胶涂层的微纤维的乙醇蒸汽传感器。 [4]
Water Vapor Sensor
A water vapor sensor system using direct absorption spectroscopy was developed based on a novel circular prism array multi-pass cell (CPA-MPC). [1] Antimony trioxide thin films deposited by vacuum thermal evaporation onto heated glass substrates are analyzed as water vapor sensors, along with the study of their morpho-structural and electrical properties. [2] The first is a water vapor sensor that is used to verify if the applied gas is human breath. [3]基于新型圆棱镜阵列多通道池(CPA-MPC)开发了一种使用直接吸收光谱的水蒸气传感器系统。 [1] 通过真空热蒸发沉积在加热的玻璃基板上的三氧化锑薄膜作为水蒸气传感器进行分析,同时研究它们的形态结构和电学特性。 [2] 第一个是水蒸气传感器,用于验证应用的气体是否是人的呼吸。 [3]
Acid Vapor Sensor
Thin films of these COFs are highly sensitive colorimetric acid vapor sensors with a detection limit as low as 35 μg L-1 and a response range of at least 4 orders of magnitude. [1] The copolymer showed distinct fluorescent when irradiated with UV light and can be used as acid vapor sensor in solid state. [2] In this study, the acetic acid vapor sensor was developed by depositing polyethyleneimine (PEI) layer onto the two QCM substrates using well-known self-assembled monolayers (SAM) method. [3]这些 COF 薄膜是高灵敏度的比色酸蒸汽传感器,检测限低至 35 μg L-1,响应范围至少为 4 个数量级。 [1] 该共聚物在紫外光照射下显示出明显的荧光,可用作固态酸蒸气传感器。 [2] 在这项研究中,醋酸蒸汽传感器是通过使用众所周知的自组装单分子层 (SAM) 方法将聚乙烯亚胺 (PEI) 层沉积到两个 QCM 基板上而开发的。 [3]
Acetone Vapor Sensor
The excellent sensing properties were ascribed to the synergistic effects between ZnO nanosheets and GO, which included a unique 2-D structure, large specific surface area, suitable particle size, and abundant in-plane mesopores, which contributed to the advance of novel acetone vapor sensors and could provide some references to the synthesis of 2-D graphene-like metals oxide nanosheets. [1] For acetone vapor sensors with a film made of polymethyl methacrylate (PMMA), this range is equal to 0. [2] Parameters of the acetone vapor sensor based on butyl acetate film are given. [3]优异的传感性能归因于 ZnO 纳米片和 GO 之间的协同效应,包括独特的二维结构、大的比表面积、合适的粒径和丰富的面内介孔,这有助于新型丙酮蒸气的发展传感器,并可以为二维石墨烯类金属氧化物纳米片的合成提供一些参考。 [1] 对于带有由聚甲基丙烯酸甲酯 (PMMA) 制成的薄膜的丙酮蒸汽传感器,该范围等于 0。 [2] 给出了基于醋酸丁酯薄膜的丙酮蒸汽传感器的参数。 [3]
Peroxide Vapor Sensor
This study presents the fabrication of a high-performance hydrogen peroxide vapor sensor based on ZnO film doped with different concentration of La using the high-frequency magnetron sputtering method. [1] We present the results of studies of the nanocomposite MWCNTs/SnO2 hydrogen peroxide vapor sensors. [2]本研究介绍了使用高频磁控溅射方法制造基于掺杂不同浓度 La 的 ZnO 薄膜的高性能过氧化氢蒸汽传感器。 [1] 我们介绍了纳米复合材料 MWCNTs/SnO2 过氧化氢蒸汽传感器的研究结果。 [2]
Ga Vapor Sensor
The proposed mechanism is designed to eliminate potential fire disaster based on gas vapor sensor network. [1] We report the fabrication and characterization of quartz-based gas vapor sensor using standard Colpitts oscillator circuit. [2]所提出的机制旨在消除基于气体蒸汽传感器网络的潜在火灾灾害。 [1] 我们报告了使用标准 Colpitts 振荡器电路的基于石英的气体蒸汽传感器的制造和表征。 [2]
Optical Vapor Sensor
A simple optical vapor sensor based on conventional Scotch adhesive tape, for analyzing ethanol–methanol mixtures, is proposed and demonstrated. [1] A simple optical vapor sensor based on conventional Scotch adhesive tape, for analyzing ethanol–methanol mixtures, is proposed and demonstrated. [2]提出并演示了一种基于传统 Scotch 胶带的简单光学蒸汽传感器,用于分析乙醇-甲醇混合物。 [1] 提出并演示了一种基于传统 Scotch 胶带的简单光学蒸汽传感器,用于分析乙醇-甲醇混合物。 [2]
Fa Vapor Sensor Fa 蒸汽传感器
Investigations of response–recovery characteristics in the 50–300oC operating temperature range reveal that the optimal operating temperature for PG, DMF and FA vapor sensors, taking into account both high response and acceptable response and recovery times are about 200 and 220oC, respectively. [1] Investigations of response–recovery characteristics in the 50–300oC operating temperature range reveal that the optimal operating temperature for PG, DMF and FA vapor sensors, taking into account both high response and acceptable response and recovery times are about 200 and 220oC, respectively. [2]对 50-300oC 工作温度范围内的响应恢复特性的研究表明,考虑到高响应和可接受的响应和恢复时间,PG、DMF 和 FA 蒸汽传感器的最佳工作温度分别约为 200 和 220oC。 [1] 对 50–300oC 工作温度范围内的响应恢复特性的研究表明,考虑到高响应和可接受的响应和恢复时间,PG、DMF 和 FA 蒸汽传感器的最佳工作温度分别约为 200 和 220oC。 [2]
Amine Vapor Sensor 胺蒸气传感器
This paper-based amine vapor sensor exhibits high sensitivity with a relatively low detection limit at 3. [1] Here, we propose a novel “turn-on” fluorescence NH3/amine vapor sensor by depositing the CH3NH3PbBr3 (MAPbBr3) on the mesoporous TiO2 (mp-TiO2) layer. [2]这种纸基胺蒸气传感器具有高灵敏度,检测限相对较低,为 3。 [1] 在这里,我们通过在介孔 TiO2 (mp-TiO2) 层上沉积 CH3NH3PbBr3 (MAPbBr3) 提出了一种新型的“开启”荧光 NH3/胺蒸汽传感器。 [2]
Ammonium Vapor Sensor 铵蒸气传感器
In this work, we have coated 0, 1, 3, and 5 wt% of Erbium (Er)-doped tin oxide (SnO2) films on glass using a simple nebulizer spray pyrolysis method to make an ammonia vapor sensor with remarkable sensitivity. [1] The behavior of the polymer-based optical ammonia vapor sensors in response to various concentrations of ammonia vapors, ranging from 5 to 135 ppm, was investigated, including the response time and response amplitude. [2]在这项工作中,我们使用简单的雾化器喷雾热解方法在玻璃上涂覆了 0、1、3 和 5 wt% 的铒 (Er) 掺杂氧化锡 (SnO2) 薄膜,以制造具有显着灵敏度的氨蒸汽传感器。 [1] 研究了基于聚合物的光学氨蒸气传感器响应各种浓度的氨蒸气(从 5 到 135 ppm)的行为,包括响应时间和响应幅度。 [2]
vapor sensor array
An optical organic vapor sensor array based on colorimetric or fluorescence changes quantified by spectroscopy provides an efficient method for realizing rapid identification and detection of organic vapor, but improving the sensitivity of the optical organic vapor sensor is challenging. [1] Vapor sensor arrays composed of a few sensor materials have the potential to discriminate TATP, but the stability of the sensor array is always a tricky problem since each sensor may encounter a device fault. [2]基于光谱量化的色度或荧光变化的光学有机蒸气传感器阵列为实现有机蒸气的快速识别和检测提供了一种有效的方法,但提高光学有机蒸气传感器的灵敏度具有挑战性。 [1] 由几种传感器材料组成的蒸汽传感器阵列具有区分 TATP 的潜力,但传感器阵列的稳定性始终是一个棘手的问题,因为每个传感器都可能遇到设备故障。 [2]