Multifunctional Sensor(多功能传感器)研究综述
Multifunctional Sensor 多功能传感器 - This fabricated ZnO/V2O5 electrode exhibited high sensitivity and a stable combined temperature, glucose, and pH sensor which is promising for development of multifunctional sensors in next generation wearables. [1] Thermoresponsive hydrogels have been received myriad attention and applied in numerous fields of soft robots, artificial muscles, and multifunctional sensors. [2] The advancement of the Internet of Things (IoT) has promoted the rapid development of low-power and multifunctional sensors. [3] Advances in carbon nanotube (CNT) based composites over the past decade have demonstrated broad potential of utilizing them as multifunctional sensors because of their unique electrical properties. [4] This report demonstrates the multifunctional sensor based on p-NiO/n-CdS rectifying junction on ITO coated PET flexible substrate using low-temperature all solution processed deposition technique for UV-vis photodetection and breath monitoring applications. [5] The preparation of stable, reliable and multifunctional sensors requires constant research. [6] This report demonstrates for the first time the direct growth of the molybdenum disulfide (MoS2) on flexible pencil eraser substrate by cost-effective hydrothermal synthesis procedure and its application as a multifunctional sensor to monitor human appendage movements and breath pattern for smart personal health care services. [7] L could be used as a multifunctional sensor to sequentially detect In3+ and Fe3+ through fluorescence enhancement and fluorescence quenching in DMF/H2 O buffer solutions. [8] High-sensitivity detection capability of the Sm-MOF can enrich the application of samarium complexes in multifunctional sensors. [9] The multifunctional sensors assembled by the hydrogel exhibit both high strain sensitivity (gauge factor ≈11. [10] The multifunctional sensors for strain and temperature are fabricated based on ionogel. [11] The excellent mechanical properties and high conductivity guarantee that the PSAB hydrogel can successfully serve as a multifunctional sensor for detecting small activities and large-scale movements of the human body through strain and pressure changes. [12] Mechanochromic molecules, which can change their luminescence characteristics after mechanical stimulus, have received an increasing interest due to their promising applications in multifunctional sensors and molecular switches. [13] The design of multifunctional sensors based on biocompatible hybrid materials consisting of conjugated polythiophene-quantum dots for multiple environmental pollutants is a promising strategy for the development of new monitoring technologies. [14] Such materials are technologically significant opportunities for renewable CNCs in flexible organic field-effect transistors and multifunctional sensors. [15] Fabrication of metal-organic frameworks (MOFs) based multifunctional sensors for various environmental pollutants represents a promising solution to the development of novel monitoring technologies. [16] Surprisingly, the film could be assembled as a multifunctional sensor to actively monitor real-time physical and infection related signals such as temperature, moisture, pH, NH3, and human movements even at sweat states. [17] The construction of multifunctional sensors has attracted considerable attention due to their multifunctional properties, such as high sensitivity and rapid detection. [18] The multifunctional sensory actuatable materials may lead to the next-generation soft robots of higher levels of autonomy and complexity with self-diagnostic feedback control. [19] Flexible flax fabric (FF) coated with CNT and nickel serving as multifunctional sensor are prepared through a cost-effective dip-coating and electroless deposition technology. [20] The state-of-art of present flexible pressure and strain sensors, temperature sensors, position sensors and multifunctional sensors based on capacitance, voltage and resistance sensing technologies, are also systematically reviewed. [21] Surprisingly, the results illustrate that complex 1 has outstanding fluorescence properties and can be used as a multifunctional sensor to selectively detect colchicine, some anions, Fe3+ and nitro compounds. [22] Up to now, it is still a challenge to fabricate the stretchable and multifunctional sensor with both the capabilities of strain sensing and temperature sensing by an effective and economical method. [23] It allows the development of multifunctional sensors based on a single hardware, which includes a typical MEMS structure and mass production microprocessor, for example, PSoC (Programmable System On Chip). [24] Graphene is one of good candidates for application to multifunctional sensors due to its unique material properties, extremely high surface-to-volume ratio and ability to be effectively co-integrated on various substrates. [25] With these structures, we then demonstrate applications in energy harvesting with tailored mechanical properties and root-mean-square voltages ranging from 2 mV to 790 mV, in multifunctional sensors for robotic prosthetic interfaces with improved responsivity (for example, anisotropic responses and sensitivity of 60 mV N−1 for normal force), and in bio-integrated devices with in vivo operational capabilities. [26] We demonstrate fabrication of multifunctional sensors with simultaneous temperature, pressure, proximity, and strain (or bending) sensing capabilities, combined with heating, UV-protection features. [27] Furthermore, recent progress in wearable sensors—including pressure, strain, electrophysiological, electrochemical, temperature, and multifunctional sensors—is presented. [28] Here, we outlined the most common types of wearable electronics for monitoring human health information, including force sensors, temperature sensors, physiological biochemical sensors, and multifunctional sensors. [29] Multifunctional sensors have attracted great interests as potential candidates for application of human health and ambient circumstance monitoring devices. [30] In the present work, we report green synthesized unmodified silver nanoparticles from Moringa oleifera’s bark extract (AgNP-MO) as multifunctional sensor for hazardous Cu(II) ion with high selectivity. [31] Multifunctional sensors with these features are problematic and challenging to accomplish. [32] Subsequently, a multifunctional sensor was employed to detect CH3COOH and poisonous HS− anions. [33] A flexible hybrid film consisting of graphene nanoplatelets (GNPs) and multi-walled carbon nanotubes (MWCNTs) was prepared and employed as a multifunctional sensor to monitor temperature and liquid leakage, based on the piezoresistive effect. [34] Subsequently, a multifunctional sensor was employed to detect CH3COOH, as well as the poisonous ions Al3+ and Cr2O72−. [35] Due to rapid advancement in technology, recently a significant amount of work has been carried out in the field of multi-mode sensor and multifunctional sensor. [36] Compound 1, as the first MOF based luminescence probe for both Cu2+ and UO22+ ions, provides insight into developing MOF-based multifunctional sensors for both nonradioactive and radioactive elements. [37] Herein, we introduce the first snow-based triboelectric nanogenerator (snow-TENG) that can be used as an energy harvester and a multifunctional sensor based on the principle of snow-triboelectrification. [38] Such results provide the MIM devices can be used as multifunctional sensors. [39] Herein, this study presents a graphene and glycerol solution-based multifunctional sensor with ultra-high stretchability and sensitivity. [40]这种制造的 ZnO/V2O5 电极表现出高灵敏度和稳定的温度、葡萄糖和 pH 传感器组合,有望用于开发下一代可穿戴设备中的多功能传感器。 [1] 热响应水凝胶已受到广泛关注,并应用于软机器人、人造肌肉和多功能传感器等众多领域。 [2] 物联网(IoT)的进步促进了低功耗、多功能传感器的快速发展。 [3] 在过去十年中,基于碳纳米管 (CNT) 的复合材料的进展已经证明了将它们用作多功能传感器的广泛潜力,因为它们具有独特的电学特性。 [4] 本报告展示了基于 p-NiO/n-CdS 整流结在 ITO 涂层 PET 柔性基板上的多功能传感器,该传感器使用低温全溶液处理沉积技术用于紫外可见光检测和呼吸监测应用。 [5] 稳定、可靠和多功能传感器的制备需要不断的研究。 [6] 本报告首次展示了通过具有成本效益的水热合成工艺在柔性铅笔橡皮擦基板上直接生长二硫化钼 (MoS2),并将其作为多功能传感器用于监测人体附属物运动和呼吸模式,以实现智能个人保健服务. [7] L可用作多功能传感器,在DMF/H2O缓冲溶液中通过荧光增强和荧光猝灭依次检测In3+和Fe3+。 [8] Sm-MOF的高灵敏度检测能力可以丰富钐配合物在多功能传感器中的应用。 [9] 由水凝胶组装的多功能传感器既表现出高应变灵敏度(应变系数≈11. [10] 应变和温度的多功能传感器是基于离子凝胶制造的。 [11] 优异的机械性能和高导电性保证了PSAB水凝胶可以成功地作为多功能传感器,通过应变和压力变化检测人体的小活动和大规模运动。 [12] 机械变色分子可以在机械刺激后改变其发光特性,由于其在多功能传感器和分子开关中的广阔应用前景而受到越来越多的关注。 [13] 基于由共轭聚噻吩-量子点组成的生物相容性混合材料的多功能传感器的设计可用于多种环境污染物的检测,是开发新监测技术的有前景的策略。 [14] 这种材料在柔性有机场效应晶体管和多功能传感器中为可再生 CNCs 提供了重要的技术机会。 [15] 为各种环境污染物制造基于金属有机框架 (MOF) 的多功能传感器代表了开发新型监测技术的有希望的解决方案。 [16] 令人惊讶的是,该薄膜可以组装成多功能传感器,以主动监测实时身体和感染相关信号,例如温度、湿度、pH、NH3 和人体运动,即使在出汗状态下也是如此。 [17] 多功能传感器的构建由于其高灵敏度和快速检测等多功能特性而引起了相当大的关注。 [18] 多功能感官可驱动材料可能会导致具有自我诊断反馈控制的具有更高自主性和复杂性的下一代软机器人。 [19] 通过具有成本效益的浸涂和化学沉积技术制备了涂有 CNT 和镍的柔性亚麻织物 (FF) 作为多功能传感器。 [20] 系统综述了目前基于电容、电压和电阻传感技术的柔性压力和应变传感器、温度传感器、位置传感器和多功能传感器的研究现状。 [21] 令人惊讶的是,结果表明复合物1具有出色的荧光特性,可用作多功能传感器,选择性地检测秋水仙碱、某些阴离子、Fe3+和硝基化合物。 [22] 到目前为止,通过有效且经济的方法制造兼具应变传感和温度传感能力的可拉伸多功能传感器仍然是一个挑战。 [23] 它允许基于单个硬件开发多功能传感器,其中包括典型的 MEMS 结构和批量生产的微处理器,例如 PSoC(可编程片上系统)。 [24] 石墨烯因其独特的材料特性、极高的表面积与体积比以及在各种基板上有效共集成的能力而成为多功能传感器应用的良好候选者之一。 [25] 有了这些结构,我们随后展示了在具有定制机械性能和 2 mV 至 790 mV 范围内的均方根电压的能量收集中的应用,在用于机器人假肢接口的多功能传感器中具有改进的响应度(例如,各向异性响应和 60 的灵敏度) mV N-1 表示法向力),以及具有体内操作能力的生物集成设备。 [26] 我们展示了多功能传感器的制造,该传感器具有同时温度、压力、接近度和应变(或弯曲)传感能力,并结合了加热、紫外线防护功能。 [27] 此外,还介绍了可穿戴传感器(包括压力、应变、电生理、电化学、温度和多功能传感器)的最新进展。 [28] 在这里,我们概述了用于监测人体健康信息的最常见的可穿戴电子设备类型,包括力传感器、温度传感器、生理生化传感器和多功能传感器。 [29] 多功能传感器作为人类健康和环境监测设备应用的潜在候选者引起了极大的兴趣。 [30] 在目前的工作中,我们报告了来自辣木树皮提取物 (AgNP-MO) 的绿色合成未改性银纳米颗粒作为具有高选择性的有害 Cu(II) 离子的多功能传感器。 [31] 具有这些特性的多功能传感器是有问题的并且难以完成。 [32] 随后,使用多功能传感器检测 CH3COOH 和有毒的 HS− 阴离子。 [33] 基于压阻效应,制备了一种由石墨烯纳米片(GNP)和多壁碳纳米管(MWCNT)组成的柔性混合膜,并用作多功能传感器来监测温度和液体泄漏。 [34] 随后,采用多功能传感器检测 CH3COOH,以及有毒离子 Al3+ 和 Cr2O72-。 [35] 由于技术的快速进步,最近在多模传感器和多功能传感器领域进行了大量工作。 [36] 化合物 1 作为第一个基于 MOF 的 Cu2+ 和 UO22+ 离子发光探针,为开发用于非放射性和放射性元素的基于 MOF 的多功能传感器提供了见解。 [37] 在此,我们介绍了第一款基于雪地摩擦起电原理的可用作能量收集器和多功能传感器的雪基摩擦纳米发电机(snow-TENG)。 [38] 这样的结果提供了 MIM 设备可以用作多功能传感器。 [39] 在此,本研究提出了一种基于石墨烯和甘油溶液的多功能传感器,具有超高的拉伸性和灵敏度。 [40]
Flexible Multifunctional Sensor
We demonstrate a self-powered, flexible multifunctional sensor by combining a polyvinylidene difluoride film with a microstructured jamming layer. [1] However, achieving flexible multifunctional sensors combining excellent sensing of temperature, strain, and pressure with a single material is still challenging. [2] Herein efficient thermal management realizes highly accurate flexible multifunctional sensor sheets using a low thermal conductive medium as a thermal barrier. [3]我们通过将聚偏二氟乙烯薄膜与微结构化干扰层相结合,展示了一种自供电、灵活的多功能传感器。 [1] 然而,实现将出色的温度、应变和压力传感与单一材料相结合的灵活多功能传感器仍然具有挑战性。 [2] 在此,有效的热管理使用低导热介质作为热障实现了高精度的柔性多功能传感器片。 [3]
Powered Multifunctional Sensor 动力多功能传感器
In response to the testing requirements of downhole positive displacement motor (PDM), this research proposes a self-powered multifunctional sensor based on the triboelectric nanogenerator that can simultaneously measure the rotating speed, rotating angle and abrasion. [1] Here, we present a self-powered multifunctional sensor (SPMS) based on hybridization with a novel design of a piezoelectrically curved spacer that functions concurrently with a zigzag shaped triboelectric harvester for a human biomechanical monitoring device. [2] This kind of free-standing self-powered multifunctional sensors has great application prospects in the fields of healthcare and artificial intelligence in the future. [3]针对井下容积式马达(PDM)的测试需求,本研究提出了一种基于摩擦纳米发电机的自供电多功能传感器,可同时测量转速、旋转角度和磨损。 [1] 在这里,我们提出了一种基于杂交的自供电多功能传感器 (SPMS),该传感器采用压电弯曲间隔器的新颖设计,该间隔器与用于人体生物力学监测设备的锯齿形摩擦电采集器同时发挥作用。 [2] 这种独立式自供电多功能传感器在未来医疗保健和人工智能领域具有巨大的应用前景。 [3]
3d Multifunctional Sensor
Thixotropic inks were formulated by dispersing nanoclay, carbon black, and polymer in an organic solvent, and then 3D multifunctional sensors were prepared by direct ink writing (DIW). [1] Herein, the stimulus responsive assembly of complex 3D structures driven by temperature-responsive hydrogels is demonstrated for applications in 3D multifunctional sensors. [2]通过将纳米粘土、炭黑和聚合物分散在有机溶剂中来配制触变墨水,然后通过直接墨水书写 (DIW) 制备 3D 多功能传感器。 [1] 在这里,由温度响应水凝胶驱动的复杂 3D 结构的刺激响应组装被证明可用于 3D 多功能传感器。 [2]
multifunctional sensor developed
A systematic interpretation of the undoped and Fe doped ZnO based multifunctional sensor developed employing economic and facile low-temperature hydrothermal method is reported. [1] In this contribution, we demonstrate a low cost, scalable, flexible and reproducible multifunctional sensor developed by dry drawing pencil traced graphitic track on polyethylene terephthalate (PET) sheet. [2]报告了采用经济和简便的低温水热法开发的未掺杂和 Fe 掺杂 ZnO 基多功能传感器的系统解释。 [1] 在这篇文章中,我们展示了一种低成本、可扩展、灵活和可重复的多功能传感器,该传感器是通过在聚对苯二甲酸乙二醇酯 (PET) 片材上干画铅笔追踪石墨轨迹而开发的。 [2]
multifunctional sensor network
The Networked Elements for Resin Visualization and Evaluation (NERVE) [19] based on the concept of distributed multifunctional sensor network of SMART (Stanford Multi-ActuatorReceiver Transduction) Layer [20] can monitor the manufacturing parameters (resin flow front and cure state) in the Liquid Composites Molding (LCM) process effectively. [1] To achieve this goal, Stanford Structures and Composites Lab (SACL) has developed a smart wing which embeds a multifunctional sensor network on the surface layup of the wing [1]. [2]基于 SMART(Stanford Multi-ActuatorReceiver Transduction)层 [20] 的分布式多功能传感器网络概念的树脂可视化和评估网络元件(NERVE)[19] 可以监控制造参数(树脂流动前沿和固化状态)液体复合材料成型 (LCM) 工艺有效。 [1] 为了实现这一目标,斯坦福结构和复合材料实验室 (SACL) 开发了一种智能机翼,该机翼在机翼的表面铺层上嵌入了多功能传感器网络 [1]。 [2]