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Chemical sensors principles

Current MEMS Chemical Sensor Principles Materials... [Pg.1563]

Chemical and Biological Sensors Current MEMS Chemical Sensor Principles Materials Selection Conjugated Polymer Sensors 14-13... [Pg.526]

Several commercial intelligent gas sensor array instruments are now available in the market covering a variety of chemical sensor principles, system design, and data analysis techniques (Figure 15.4). [Pg.430]

J. Janata, Principles of Chemical Sensors, Plenum Press, New York, 1989. [Pg.26]

We scrutinize issues dealing with requirements of high sensitivity and response selectivity of electrophysical parameters in reference to the gas monitored or the type of active particles under study as well as other requirements put forward to adsorbents of chemical sensors. We discuss principles underlying the basis of solving these problems. We dwell on the issue of the type of crystal of adsorbents examined, which is directly linked to the character of intracrystallite contacts. [Pg.2]

Let us start with a definition. Semiconductor chemical sensor is an electronic device designed to monitor the content of particles of a certain gas in surrounding medium. The operational principle of this device is based on transformation of the value of adsorption directly into electrical signal. This signal corresponds to amount of particles adsorbed from surrounding medium or deposited on the surface of operational element of the sensor due to heterogeneous diemical reaction. [Pg.5]

Principles and Characteristics Extraction or dissolution methods are usually followed by a separation technique prior to subsequent analysis or detection. While coupling of a sample preparation and a chromatographic separation technique is well established (Section 7.1), hyphenation to spectroscopic analysis is more novel and limited. By elimination of the chromatographic column from the sequence precol-umn-column-postcolumn, essentially a chemical sensor remains which ensures short total analysis times (1-2 min). Examples are headspace analysis via a sampling valve or direct injection of vapours into a mass spectrometer (TD-MS see also Section 6.4). In... [Pg.449]

Chemical sensors may be classified according to the operating principle of the transducer as optical, electrochemical, electrical, mass sensitive, etc. [Pg.78]

The goal of this book is to cover the full scope of electrochemical sensors and biosensors. It offers a survey of the principles, design and biomedical applications of the most popular types of electrochemical devices in use today. The book is aimed at all scientists and engineers who are interested in developing and using chemical sensors and biosensors. By discussing recent advances, it is hoped to bridge the common gap between research literature and standard textbooks. [Pg.22]

This chapter provides an overview of the basic principles and designs of such sensors. A chemical sensor to detect trace explosives and a broadband fiber optic electric-field sensor are presented as practical examples. The polymers used for the trace explosive sensor are unpoled and have chromophores randomly orientated in the polymer hosts. The electric field sensor uses a poled polymer with chromophores preferentially aligned through electrical poling, and the microring resonator is directly coupled to the core of optical fiber. [Pg.7]

The FPI principle can also be used to develop thin-film-coating-based chemical sensors. For example, a thin layer of zeolite film has been coated to a cleaved endface of a single-mode fiber to form a low-finesse FPI sensor for chemical detection. Zeolite presents a group of crystalline aluminosilicate materials with uniform subnanometer or nanometer scale pores. Traditionally, porous zeolite materials have been used as adsorbents, catalysts, and molecular sieves for molecular or ionic separation, electrode modification, and selectivity enhancement for chemical sensors. Recently, it has been revealed that zeolites possess a unique combination of chemical and optical properties. When properly integrated with a photonic device, these unique properties may be fully utilized to develop miniaturized optical chemical sensors with high sensitivity and potentially high selectivity for various in situ monitoring applications. [Pg.159]

Horvath, R. Skivesen, N. Larsen, N. B. Pedersen, H. C., Reverse symmetry waveguide for optical biosensing, In Frontiers in Chemical Sensors. Novel Principles and Techniques Orellana, G. Moreno Bondi, M. C., Eds. Springer Series on Chemical Sensors and Biosen sors Springer, Berlin, 2005, Vol. 3, 279 301... [Pg.439]

For the fabrication of chemical sensors, either the unique properties of the silicon electrode itself or a variation in PS properties with absorption of molecules at the large internal surface, are exploited for sensing. Both principles are addressed below. [Pg.219]

The working principle of the sensor is simple. If the tip of the sensor, which contains the electrodes, is immersed in a liquid free of HF, an anodic oxide is formed and the anodic current decreases within a second to very low values the LED is off. For the case of a liquid containing more than 5% HF, a constant anodic current flows which is only limited by the series resistor and the LED emits with its maximum intensity. If the liquid contains between 0.5% and 5% HF the intensity of the LED becomes roughly proportional to the HF concentration. In contrast to other chemical sensors where the electrodes are very sensitive to contamination or drying, the HF sensor is quite robust. The sensor electrode can be... [Pg.219]

A shadow-mask technique has been applied for the local metal deposition to exclude metal residues on other designs processed on the same wafer (Fig. 4.2b). Such metal residues may be caused by imperfections in the patterned resist due to topographical features on the processed CMOS wafers or dust particles. The metal film is only deposited in those areas on the wafer, where it is needed for electrode coverage on the microhotplates. This also renders the lift-off process easier since no closed metal film is formed on the wafer, so that the acetone has a large surface to attack the photoresist. Another advantage of the local metal lift-off process is its full compatibility with the fabrication sequence of chemical sensors based on other transducer principles [20]. [Pg.33]

Janata, J., Principles of Chemical Sensors, Plenum Press, New York, 1989. Some sensor specialists regard this as the definitive work on the subject. While extremely dated, its introductory sections provide a clear, uncluttered introduction to the different modes of sensor operation. [Pg.332]

J. JANATA, "Principles of Chemical Sensors", Plenum Press, New York, 1988. A.P.F, TURNER and G.S. WILSON, "Biosensors. Fundamentals and Applications", Oxford University Press, Oxford, 1987. [Pg.252]

Liess, M. and Steffes, H. (2000) The modulation of thermoelectric power by chemisorption a new detection principle for microchip chemical sensors. /. Electrochem. Soc. 147, 3151-3153. Tran-Minh, C. and Vallin, D. (1978) Anal. Chem. 50, 1874. [Pg.62]

See other pages where Chemical sensors principles is mentioned: [Pg.1575]    [Pg.538]    [Pg.1575]    [Pg.538]    [Pg.218]    [Pg.503]    [Pg.22]    [Pg.210]    [Pg.568]    [Pg.588]    [Pg.209]    [Pg.145]    [Pg.65]    [Pg.167]    [Pg.293]    [Pg.14]    [Pg.105]    [Pg.26]    [Pg.177]    [Pg.414]    [Pg.488]    [Pg.326]    [Pg.568]    [Pg.588]    [Pg.1]    [Pg.63]    [Pg.90]   
See also in sourсe #XX -- [ Pg.418 , Pg.504 ]



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