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Sensors solid state

T. A. Core, W. K. Tsang, S. J. Sherman. Fabrication technology for an integrated surface-machined sensor. Solid State Technol 3(5 39—44, 1993. [Pg.66]

H. Kaden, H. Jahn, and M. Berthold, Study of the glass/polypyrrole interface in an all-solid-state pH sensor. Solid State Ionics 169, 129-133 (2004). [Pg.325]

Gopel, W., Reinhardt, G. and Rosch, M. (2000) Trends in the development of solid state amperometric and potentiometric high temperature sensors, Solid State Ionics, 136/7, 519-31. [Pg.240]

Kale, G.M., Davidson, A.J. and Fray, D.J. (1996) Investigation into an improved design of C02 sensor, Solid State Ionics 86/8, 1107-10. [Pg.241]

Amperometric sensing of gases is based on solid ion-conducting materials, as described for potentiometric gas sensors. Solid-state amperometric gas sensors measure the limiting current (ij) flowing across the electrochemical cell upon application of a fixed voltage so that the rate of electrode reaction is controlled by the gas transport across the cell. The diffusion barrier consists of small-hole porous ceramics. The limiting current satisfies the relationship ... [Pg.204]

The aim of this chapter is to review the current state of knowledge in ionic materials with crystallite dimensions less than 100 nm, systems which sometimes are referred to as nanoionics. The chapter will detail the preparation, characterization and the important applications of these materials, especially in sensors, solid-state batteries, and fuel cells. Particular focus will be placed on ionic transport in these materials, as this is a topic of considerable contemporary interest, and where conflicting reports exist of enhanced diffusion in nanocrystals. [Pg.79]

Eastman, C.D. and Etsell, T.H. (2000) Thick/thin film sulfur oxide chemical sensor. Solid State Ionics, 136-137, 639-45. [Pg.472]

Li, F., Tang, Y. and Li, L. (1996) Distribution of oxygen potential in ZrO2-based solid electrolyte and selection of reference electrode of oxygen sensor. Solid State Ionics, 86—88, 1027-31. [Pg.473]

Dubbe, A. (2008) Influence of the sensitive zeolite material on the characteristics of a potentiometric hydrocarbon gas sensor. Solid- State Ionics, 179, 1645-7. [Pg.474]

Ramirez-Salgado, J. and Fabry, P. (2003) Study of CO2 electrodes in open devices of potentiometric sensors. Solid State Ionics,... [Pg.475]

Zosel, J., Westphal, D., Jakobs, S., Muller, R. and Guth, U. (2002) Au-oxide composites as HC-sensitive electrode materials for mixed potential gas sensors. Solid State Ionics, 152—153, 525—9. [Pg.482]

Nakatou, M. and Miura, N. (2005) Detection of combustible hydrogen-containing gases by using impedancemetric zirconia-based water-vapor sensor. Solid State Ionics, 176, 2511-15,... [Pg.488]

Jacob, K.T. and Ramasesha, S.K. (1989) Design of temperature-compensated reference electrodes for non-isothermal galvanic sensors. Solid State Ionics, 34. 161-6. [Pg.490]

MaskeU, W.C., Progress in the development of zirconia gas sensors. Solid State Ionics 134 (2000) 43-50. [Pg.41]

Burkhard, D.J.M., Hanson, B., and Uhner, G.C., ZrOj oxygen sensors An evaluation of behavior at temperatures as low as 300°C, Solid State Ionics 47 (1991) 169-175. Can, Z.Y. et al., Detection of carbon monoxide by using zirconia oxygen sensor, Solid State Ionics 79 (1995) 344-348. [Pg.194]

Hotzel G. and Weppner W., Application of fast ionic conductors in solid state galvanic cells for gas sensors. Solid State Ionics, 18/19, 1223-1227, 1986. [Pg.31]

Jamnik, J., Kamp, B., Merkle, R. and Maier, J. (2002), Space charge inflnenced oxygen incorporation in oxides in how far does it contribnte to the drift of Taguchi sensors Solid State Ionics, 150(1-2), 157-66. [Pg.294]

Roder-Roith, U., Rettig, E, Sahner, K., Roder, T, Janek, J. and Moos, R. (2011), Perovskite-type proton conductor for novel direct ionic thermoelectric hydrogen sensor. Solid State Ionics, 192(1), 101-4. [Pg.295]

Sahner, K., Hagen, G., Schonaner, D., ReiB, S. and Moos, R. (2008) Zeohtes - Versatile materials for gas sensors. Solid State Ionics 179,2416-23. [Pg.465]

Chu, W.F., Fischer, D., Erdmann, H., Ilgenstein, M., Koppen, H. and Leonhard, V. (1992), Thin and thick film electrochemical CO2 sensors . Solid State Ionics, 53-56, part 1,80-4. [Pg.532]

Salam, F, Bredikhin, S., Birke, P. and Weppner, W. (1998), Effect of the thickness of the gas-sensitive layer on the response of solid state electrochemical CO2 sensors , Solid State Ionics, 110,3-4,319-25. [Pg.535]

Potyrailo, R. et al. Label-free biosensing using passive radio-frequency identification sensors. Solid- State Sens., Actuators, Microsyst. Int. Conf., pp. 2378-2380,2009. [Pg.232]

Moneyron, J.E., de Roy, A., and Besse, J. P. 1991c. Protonic conductivity of hydrotdcite-type compound thick films Application to a humidity sensor. Solid State Ionics 46 175-81. [Pg.167]

Yude W, Xinghui W, Yangeug L, Zhenlai Z. Mesostructured Sn02 as sensing material for gas sensors. Solid-State Electron 2004 48(5) 627-32. [Pg.537]

N. Matsui [1981] Complex-Impedance Analysis for the Development of Zirconia Oxygen Sensors, Solid State Ionics 3/4, 525-529. [Pg.566]


See other pages where Sensors solid state is mentioned: [Pg.218]    [Pg.515]    [Pg.552]    [Pg.476]    [Pg.487]    [Pg.487]    [Pg.218]    [Pg.211]    [Pg.213]    [Pg.539]   
See also in sourсe #XX -- [ Pg.149 ]




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