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Arrhenius and non-Arrhenius conductivities in intercalated polymer electrolytes
The Journal of Chemical Physics, 1998Intercalated polymer electrolytes (IPEs), Cd0.75PS3A0.5(PEO) [A=Li, Na, K, Cs], formed by the insertion of alkali metal ions solvated by polyethylene oxide (PEO) into the interlamellar space of the layered insulating cadmium thio-phosphate form an interesting class of materials.
Jeevanandam, P, Vasudevan, S
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Multiplicative algorithm for discriminating between Arrhenius and non-Arrhenius behaviour
Chemometrics and Intelligent Laboratory Systems, 2014Abstract The Arrhenius equation kA = Ae− E/Rt has found numerous applications throughout chemical kinetics for diverse rate processes. This equation involves the assumption that the pre-exponential factor, A, does not vary with temperature. For simple reactions, deviations from this equation are usually quite small, and in only a few instances are ...
Raúl Martín-Martín +2 more
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2020
Abstract The Arrhenius equation describes the way in which the speed of a chemical reaction varies exponentially with temperature. This chapter describes the thermodynamics of chemical reactions, the complexity of chemical kinetics, their explanation in terms of atomic and molecular collisions and transitionary activated states, and ...
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Abstract The Arrhenius equation describes the way in which the speed of a chemical reaction varies exponentially with temperature. This chapter describes the thermodynamics of chemical reactions, the complexity of chemical kinetics, their explanation in terms of atomic and molecular collisions and transitionary activated states, and ...
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2013
Contents The temperature dependence of reaction rates 816 Example 85.1: Determining the Arrhenius parameters 817 Brief illustration 85.1: The Arrhenius equation 817 The interpretation of the Arrhenius parameters 818
Peter Atkins +2 more
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Contents The temperature dependence of reaction rates 816 Example 85.1: Determining the Arrhenius parameters 817 Brief illustration 85.1: The Arrhenius equation 817 The interpretation of the Arrhenius parameters 818
Peter Atkins +2 more
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A-to-Z Guide to Thermodynamics, Heat and Mass Transfer, and Fluids Engineering, 2006
R. Kandiyoti, A. A. Herod
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R. Kandiyoti, A. A. Herod
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JAMA: The Journal of the American Medical Association, 1975
M A, Shampo, R A, Kyle
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M A, Shampo, R A, Kyle
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Terrestrial Magnetism and Atmospheric Electricity, 1905
Svante August Arrhenius was born on February 19, 1859, near Upsala, his father being connected with the University. He completed the period of undergraduate work in 1876, and in 1884 received the degree of Doctor of Science in the University of Upsala, being immediately after that elected Docent in the same institution.In the meantime he had been ...
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Svante August Arrhenius was born on February 19, 1859, near Upsala, his father being connected with the University. He completed the period of undergraduate work in 1876, and in 1884 received the degree of Doctor of Science in the University of Upsala, being immediately after that elected Docent in the same institution.In the meantime he had been ...
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Processing thin but robust electrolytes for solid-state batteries
Nature Energy, 2021Moran Balaish +2 more
exaly