Thermogenesis: experimental approach to a reduced transference function

E. Cesari; J. Ortin; V. Torra; J. Viñals; J. L. Macqueron; J. P. Dubes; H. Tachoire

doi:10.1016/0040-6031(80)87228-5

Thermogenesis: experimental approach to a reduced transference function

E. Cesari, J. Ortin, V. Torra, J. Viñals, J. L. Macqueron, J. P. Dubes, H. Tachoire

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Abstract

The dynamic treatment of conduction microcalorimeters must be accomplished through their transference function (TF). A systematic analysis of experimental TFs belonging to calorimeters whose dynamic characteristics are quite different (the first time constants ratio is roughly 16) shows: in order to verify the relative dynamic characteristics it is convenient to use a reduced representation of modulus (dB) and phase (rad) against a reduced scale ντ ₁. Such a representation between 0 and 30 dB does not depend on the laboratory cell and the kind of detector: in this representation, TFs associated with materials of high conductivity coincide within the range 0 < ντ₁ < 4. For materials of low conductivity, the TFs group in the range 0 < ντ₁ < 1. It seems feasible, then, to use a reduced TF irrespective of the type of calorimeter.

Original language	English (US)
Pages (from-to)	269-274
Number of pages	6
Journal	Thermochimica Acta
Volume	40
Issue number	2
DOIs	https://doi.org/10.1016/0040-6031(80)87228-5
State	Published - 1980
Externally published	Yes

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title = "Thermogenesis: experimental approach to a reduced transference function",

abstract = "The dynamic treatment of conduction microcalorimeters must be accomplished through their transference function (TF). A systematic analysis of experimental TFs belonging to calorimeters whose dynamic characteristics are quite different (the first time constants ratio is roughly 16) shows: in order to verify the relative dynamic characteristics it is convenient to use a reduced representation of modulus (dB) and phase (rad) against a reduced scale ντ 1. Such a representation between 0 and 30 dB does not depend on the laboratory cell and the kind of detector: in this representation, TFs associated with materials of high conductivity coincide within the range 0 < ντ1 < 4. For materials of low conductivity, the TFs group in the range 0 < ντ1 < 1. It seems feasible, then, to use a reduced TF irrespective of the type of calorimeter.",

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T2 - experimental approach to a reduced transference function

AU - Cesari, E.

AU - Ortin, J.

AU - Torra, V.

AU - Viñals, J.

AU - Macqueron, J. L.

AU - Dubes, J. P.

AU - Tachoire, H.

PY - 1980

Y1 - 1980

N2 - The dynamic treatment of conduction microcalorimeters must be accomplished through their transference function (TF). A systematic analysis of experimental TFs belonging to calorimeters whose dynamic characteristics are quite different (the first time constants ratio is roughly 16) shows: in order to verify the relative dynamic characteristics it is convenient to use a reduced representation of modulus (dB) and phase (rad) against a reduced scale ντ 1. Such a representation between 0 and 30 dB does not depend on the laboratory cell and the kind of detector: in this representation, TFs associated with materials of high conductivity coincide within the range 0 < ντ1 < 4. For materials of low conductivity, the TFs group in the range 0 < ντ1 < 1. It seems feasible, then, to use a reduced TF irrespective of the type of calorimeter.

AB - The dynamic treatment of conduction microcalorimeters must be accomplished through their transference function (TF). A systematic analysis of experimental TFs belonging to calorimeters whose dynamic characteristics are quite different (the first time constants ratio is roughly 16) shows: in order to verify the relative dynamic characteristics it is convenient to use a reduced representation of modulus (dB) and phase (rad) against a reduced scale ντ 1. Such a representation between 0 and 30 dB does not depend on the laboratory cell and the kind of detector: in this representation, TFs associated with materials of high conductivity coincide within the range 0 < ντ1 < 4. For materials of low conductivity, the TFs group in the range 0 < ντ1 < 1. It seems feasible, then, to use a reduced TF irrespective of the type of calorimeter.

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Thermogenesis: experimental approach to a reduced transference function

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