硫化氢气体传感器的研究进展

硫化氢(H_2S)是一种具有臭鸡蛋气味的腐蚀性气体,是广泛存在的环境污染物之一。H_2S为剧毒性气体,且易挥发,严重损伤人的呼吸系统,甚至神经系统和心脏器官。因此,实现H_2S气体的快速、高灵敏及实时检测对于工业生产、公共安全、环境监测和医疗健康等领域具有十分重要的意义。该文对近5年来电量型和光学型两类H_2S气体传感器在传感技术和传感材料上取得的重要进展进行了综述,并对这两类传感器所面临的问题和未来发展趋势进行了探讨。     

金属氧化物室温气敏材料的结构调控及传感机理

室温气敏材料能耗低、稳定性好、安全性高,并且有助于简化传感器的器件结构,具有很好的实际应用前景。开发具有优异室温传感性能的气敏材料成为近年来传感领域的研究热点。金属氧化物半导体材料来源广泛、环境友好、结构调控灵活,在室温气体传感性能方面取得一定的进展。本文介绍了金属氧化物气敏材料的发展历程及气体传感机理,详述了各种具有室温气敏性能的金属氧化物纳米结构,重点讨论构建金属氧化物室温传感性能的有效策略和传感机制,并对室温传感材料的未来发展进行了展望。     

超分子组装在二维材料基室温甲醛传感材料中的应用

甲醛作为室内空气中的主要挥发性有机化合物之一,对人体的健康产生了极大的威胁,因此对甲醛进行检测具有重要意义.传统的电阻式气体传感器一般基于低成本和高灵敏的金属氧化物,但其较高的操作温度和较低的选择性限制了它们的实际应用.开发高性能室温甲醛传感器迫在眉睫,其核心则是寻找性能优异的室温甲醛传感材料.二维材料由于具有独特的物理化学性质和电学性能,成为高性能室温甲醛传感器的热门候选材料.另一方面,超分子组装作为一种温和的材料修饰改性策略,也为大幅提高二维材料的室温甲醛传感性能提供了可能.本文整理了近年来基于二维材料的室温甲醛传感相关工作,总结了甲醛气体分子的传感机制,梳理了二维材料的分类与特性,归纳了用于室温甲醛传感的基于二维材料“主体”的超分子组装策略,并着重介绍了二维材料基超分子组装材料在电阻式室温甲醛传感中的应用,并对二维材料基室温甲醛传感材料的未来发展进行了展望.     

碳纳米管气体传感器研究进展

碳纳米管具有一维纳米结构、高表面吸附能力、良好的导电性和电子弹道传输特性等优异的力学、电学、物理和化学性能,成为制作纳米气体传感器的理想材料之一.近年来,各国研究者广泛开展了碳纳米管气体传感器的研究工作,并取得了许多显著成果.研究结果表明,碳纳米管气体传感器具有灵敏度高、响应速度快、尺寸小、能耗低和室温下工作等诸多特点.本文结合本研究小组近年来在碳纳米管气体传感器领域所做的大量研究工作,从环境监测、医学检测和国防军事等方面,对碳纳米管气体传感器取得的研究进展进行了综述,同时也阐述和分析了碳纳米管气体传感器的工作原理和制作过程.尽管面临诸多挑战,随着研究的不断深入,碳纳米管气体传感器仍有可能凭借其独特的性能优势成为当前商业应用气体传感器的有力竞争者.     

钼酸铋基气敏材料研究进展

气体传感器被广泛应用于检测工业和家庭中有毒有害气体。气体敏感材料是气体传感器中重要的组成部分,敏感材料的性质决定了气体传感器的性能。研制精度高、检测快、集成度高的气体检测器迫在眉睫。钼酸铋作为一种新型双金属氧化物气敏材料,具有高选择性、高敏感度的优势。本文从气敏机理、形貌控制、掺杂和复合材料构建方面对近年来钼酸铋作为气敏材料的研究进行了总结,并对钼酸铋基气敏材料未来的研究方向进行了展望。     

MXenes复合材料的发展:界面调控及结构设计

MXenes作为一类新兴的二维材料, 因具有独特的亲水性、 优异的力学性能、 丰富的表面官能团、 高导电率、 光热以及光电效应等性能而成为研究热点, 广泛应用在电磁屏蔽、 电化学储能、 生物医药、 分离、 传感器和海水淡化等领域. 虽然MXenes具有这些优异的性能, 但是其存在的与疏水性高分子相容性差、 带负电的官能团阻碍电解质运输及易氧化等问题限制了其实际应用. 近年来, 通过对MXenes进行界面调控以解决其固有缺陷, 并在此基础上对MXenes进行针对性的结构设计以提升界面稳定性, 其性能得到了进一步提升. 本文对MXenes复合材料发展过程中在界面调控和结构设计方面的研究进展进行总结, 并重点介绍了MXenes的结构和性质及MXenes在复合材料中的界面调控手段, 对MXenes复合材料的结构设计进行了阐述, 并对MXenes复合材料的发展前景进行了展望.     

SAW气体传感器聚合物敏感膜材料研究进展

声表面波(surface acoustic wave,SAW)气体传感器具有灵敏度高、选择性好、响应时间短以及体积小,携带方便等优点,因而被广泛应用于环境监测、医疗卫生、化学侦检等领域中有毒有害气体的现场实时检测。敏感膜材料的特性是决定SAW传感器性能(如灵敏度、选择性、响应时间、寿命等)的关键因素。本文首先简要介绍了SAW气体传感器的响应原理和对敏感膜材料的要求,然后重点阐述了用于SAW气体传感器的有机聚合物敏感膜材料的研究进展,最后对其研究趋势做出简单预测。     

不同种类敏感膜修饰的QCM气体传感器研究现状

石英晶体微天平(quartz crystal microbalance,QCM)是一种对质量变化敏感的器件,具有灵敏度高、成本低廉、操作简单、可实时在线检测等优点,在气体传感领域受到了广泛关注。敏感材料是石英晶体微天平气体传感器的关键组成部分,本文综述了不同敏感材料包括有机聚合物、超分子化合物、离子液体和分子液体以及近年来备受关注的纳米材料修饰的QCM对特定气体传感检测的研究现状,详细介绍了纳米材料为敏感膜的QCM气体传感器对不同气体传感检测的研究现状及相关敏感机理。最后,在国内外研究现状的基础上,展望了敏感材料的发展前景。QCM作为一种成本低廉、操作方便、测量精度高的气体传感检测器件,将会有更加广阔的应用前景。     

MXene在电化学传感器中的应用

过渡金属碳化物或氮化物(MXene)作为一种新型的二维层状材料,由于具有良好的导电性、水中分散性、高的生物相容性和稳定性等,在电化学传感领域具有巨大的应用潜力。将MXene与其他纳米材料复合,可以扬长避短,在性能上实现优势协同和功能互补,有效提高电化学传感器的灵敏度和选择性。本文按照检测物的种类进行分类,综述了基于MXene材料构建的电化学传感平台在生物标记物和环境污染物检测中的应用,并讨论了MXene材料在电化学传感领域未来研究发展和应用中所面临的挑战。     

有机智能传感材料与器件研究进展

有机光电子材料具有柔性、低成本、可大面积加工以及分子结构可调等特点,在可穿戴智能器件领域具有巨大的应用潜力.有机分子可以通过结构的设计调节其光学、电学、机械和化学等特性,从而实现丰富的传感功能.有机智能传感器具有快速响应、高选择性、高灵敏和机械柔性等优势,被广泛应用于环境监测、电子皮肤、医疗监测、人机交互等智能感知领域.本文综述了近年来有机智能传感材料与器件的研究进展,包括小分子半导体、聚合物半导体和导电聚合物等有机传感材料,以及化学传感器、温度传感器、光学传感器和机械传感器等有机智能传感器件的前沿应用,重点介绍了目前生物传感器、仿生传感器等智能感知器件和系统的发展现状,并对其未来发展过程中面临的挑战进行了分析.     

Recent advances in MXenes-based glucose biosensors

It is established that monitoring blood glucose on a daily basis is one of the most effective solutions to prevent and treat diabetes. Consequently, developing a glucose sensing platform with outstanding sensing performance occupies an indispensable position for the early diagnosis and risk assessment of diabetes. Recently, biosensor has been deemed as a promising apparatus to acquire the signals for glucose monitoring based on 2D materials. However, it is unsatisfied to deploy some materials widely as a result of some inherent defects. Carbon nanotubes have comparatively high toxicity. MoS₂ with unfavourable biocompatibility are still arduously implemented on being functionalized. Fortunately, MXene, a brand-new and rapidly developing two-dimensional material, exhibits marvellous application potential in the domain of biosensing. Therefore, it has exerted tremendous attention from diverse scientific fields owning to its remarkable properties, such as excellent hydrophilicity, metal-like conductivity, abundant surface functional groups, unique layered structure, large specific surface area and remarkable biocompatibility. This review mainly focuses on the main synthetic route of MXenes, as well as the recent advancements of biosensors involving MXenes as an electrode modifier for glucose detection. In addition, the promising prospects and challenges of glucose sensing technology based on MXenes are also discussed.     

A mini-review on MXenes as versatile substrate for advanced sensors

MXenes have emerged as versatile 2D materials that are already gaining paramount attention in the areas of energy,catalyst,electromagnetic shielding,and sensors.The unique surface chemistry,graphene-like mo rphology,high hydrophilicity,metal-like conductivity with redox capability identifies MXenes,as an ideal material for surface-related applications.This short review summarizes the most recent reports that discuss the potential application of MXenes and their hybrids as a transducer material for advanced sensors.Based on the nature of transducing signals,the discussion is categorized into three sections,which include electrochemical(bio) sensors,gas sensors,and finally,electro-chemiluminescence fluorescent sensors.The review provides a concise summary of all the analytical merits obtained subsequent to the use of MXenes,followed by endeavors that have been made to accentuate the future perspective of MXenes in sensor devices.     

Current progresses in two-dimensional MXene-based framework: prospects from superficial synthesis to energy conversion and storage applications

MXenes are regarded as a type of two-dimensional (2D) inorganic material, mainly comprising a number of transition metal carbides, nitrides, or carbonitrides atomic planes. Nevertheless, the scientific community is continuously interested in exploring and structuring the engineered-based multifunctional material for numerous applications. The MXenes-based materials in this context, have emerged as highly active compounds owing to their superior surface area, substantial interlayer spacing, highly reactive surface-active sites and surface functional group, even though, recent studies have shown significant scientific and theoretical progress related to enormous prospects in MXenes, chemical nature, robust electrochemistry and high hydrophilicity of MXenes. The role of MXenes in all kinds of strategies is still in an upgrading phase for their further improvement, and is not sufficiently summarized in the literature now. To begin with this, herein, present review article is intended to critically discuss the diversity of MXenes with respect to different composition, formulation, plasmonic, complexation, and numerous geometric and morphological aspects, along with novel construction strategies to improve their surface characteristics in all aforesaid multidimensional applications. Following that, in terms of broadening the application, this review article is envisaged to endorse the use of MXenes and their hybrid configuration in a series of emerging environmental decontamination via adsorption, photodegradation, photocatalytic fuel production via hydrogen evolution, CO₂ reduction, electrocatalytic sensing, along with membrane distillation and energy storage. In addition, comprehensive information about existing obstacles and future perspectives have been addressed. Finally, an overview is succinctly summarized and discussed regarding the emerging prospects of MXenes for their potential uses in numerous research fields. At the end, it is anticipated that this review article will pave the way for the effective use of MXenes in different fields of environmental remediation, energy conversion, storage and biomedical applications as an innovative, reliable, and multifunctional material.     

Environmental significance of wearable sensors based on MXene and graphene

Conductive layered materials such as MXenes (e.g., transition metal carbides, nitrides, and carbonitrides), graphene and their derivatives have attracted tremendous research interests in diverse fields of research for their unique structured merits and outstanding physical and chemical properties. Benefitting from their unique layered structures and fascinating multifunctional characteristic, MXenes and graphene serve as vital components in a variety of wearable devices. Especially, due to their large surface area and high electrocatalytic activity, these materials have also demonstrated great promise in biophysical and biochemical sensing systems. Following an introduction into the field, we summarize the recent progress in wearable sensors that can be accomplished by using layered materials, with a specific focus on kinematic, mechanical, thermal, pressure and strain sensors. A further large section underscores the recent progress in MXenes and graphene based wearable biochemical sensors including electrolyte monitoring, glucose monitoring, micro/mcromolecular organics metabolite, volatile gases monitoring and humidity sensors. The next section covers the sensing of small biomolecules serving as biomarkers, which are of great significance for early diagnosis and treatment of a spectrum of diseases. This review underscores the recent progress in wearable sensors to be used in different physiological and environmental signals. Finally, the review concludes with a debate on current challenges being faced and future perspectives.     

高灵敏度高选择性气敏材料--金属酞菁配合物

酞菁配合物是一类重要的光电功能材料.由于它的特殊结构使其成为高灵敏度高选择性气敏材料,具有极好的应用前景.本文在介绍酞菁配合物的结构特点、合成方法、气敏特性及其最新研究进展的基础上,讨论了酞菁配合物的气敏机理及膜结构、中心金属和取代基对气敏性的影响,并对酞菁配合物作为气敏材料的发展趋势进行了展望。     

金属有机框架及其衍生的金属氧化物在电阻式气体传感器中的应用

高灵敏和选择性的气体传感器对于实时监测大气中有毒有害气体和早期的疾病诊断具有重要的意义.目前,传统的气敏材料仍然存在着许多问题亟待解决,例如:选择性差、检测极限不够低、使用寿命短等.作为一种多孔的配位聚合物,金属有机框架材料(MOFs)由于其超高的比表面积和较大的孔隙率在气体传感器领域已经得到广泛的应用.利用MOFs自...     

Electrochemical biosensors based on Ti3C2Tx MXene: future perspectives for on-site analysis

MXenes are recently developed two-dimensional layered materials composed of early transition metal carbides and/or nitrides that provide unique characteristics for biosensor applications. This review presents the recent progress made on the usage and applications of MXenes in the field of electrochemical biosensors, including microfluidic biosensors and wearable microfluidic biosensors, and highlights the challenges with possible solutions and future needs. The multilayered configuration and high conductivity make these materials as an immobilization matrix for the biomolecule immobilization with activity retention and to be explored in the fabrication of electrochemical sensors, respectively. First, how the MXene nanocomposite as an electrode modifier affects the sensing performance of the electrochemical biosensors based on enzymes, aptamer/DNA, and immunoassays is well described. Second, recent developments in MXene nanocomposites as wearable biosensing platforms for the biomolecule detection are highlighted. This review pointed out the future concerns and directions for the use of MXene nanocomposites to fabricate advanced electrochemical biosensors with high sensitivity and selectivity. Specifically, possibilities for developing microfluidic electrochemical sensors and wearable electrochemical microfluidic sensors with integrated biomolecule detection are emphasized.     

基于MXenes的功能纤维的制备及其在智能可穿戴领域的应用

在电子信息和物联网技术的推动下,人类对可穿戴电子器件和智能织物的需求愈发突出,功能纤维作为智能可穿戴设备的重要载体,近年来获得快速发展。功能纤维的性能很大程度上取决于纤维的基础构筑单元。过渡金属碳/氮化物(MXenes)作为一种新兴的二维材料,凭借其高电导率、优异的可加工性能、可调节的表面特性以及出色的机械强度等优点,受到了极大的关注,也逐渐成为构筑功能纤维的重要单元。本文将主要综述MXenes的湿化学、熔融盐、无氟试剂刻蚀等方法和力学、电学、光学和化学稳定性等性能,阐述基于该材料制备的功能纤维在传感、储能以及其他智能领域的应用,最后讨论了基于MXenes材料的功能纤维的未来应用前景和技术挑战。     

Role of MXene surface terminations in electrochemical energy storage: A review

MXenes are a group of recently discovered 2D materials and have attracted extensive attention since their first report in 2011; they have shown excellent prospects for energy storage applications owing to their unique layered microstructure and tunable electrical properties. One major feature of MXenes is their tailorable surface terminations (e.g., −F, −O, −OH). Numerous studies have indicated that the composition of the surface terminations can significantly impact the electrochemical properties of MXenes. Nonetheless, the underlying mechanisms are still poorly understood, mainly because of the difficulties in quantitative analysis and characterization. This review summarizes the latest research progress on MXene terminations. First, a systematic introduction to the approaches for preparing MXenes is presented, which generally dominates the surface terminations. Then, theoretical and experimental efforts regarding the surface terminations are discussed, and the influence of surface terminations on the electronic and electrochemical properties of MXenes are generalized. Finally, we present the significance and research prospects of MXene terminations. We expect this review to encourage research on MXenes and provide guidance for usingthese materials for batteries and supercapacitors.