Internal flow: Difference between revisions
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{{MitoPedia | {{MitoPedia | ||
|abbr=''I''<sub>i</sub> | |abbr=''I''<sub>i</sub> [MUยทs<sup>-1</sup>] | ||
|description=Within the system boundaries, irreversible '''internal flows''' of heat and matter along gradients or internal transformations (chemical reactions) contribute to the internal entropy production, d<sub>i</sub>''S''. In contrast, [[external flow]s, ''I''<sub>e</sub>, of heat, work and matter proceed reversibly across the system boundaries (of zero thickness). | |description=Within the system boundaries, irreversible '''internal flows''' of heat and matter along gradients or internal transformations (chemical reactions) contribute to the internal entropy production, d<sub>i</sub>''S''. In contrast, [[external flow]]s, ''I''<sub>e</sub>, of heat, work and matter proceed reversibly across the system boundaries (of zero thickness). | ||
|info=[[Gnaiger_1993_Pure Appl Chem]] | |info=[[Gnaiger_1993_Pure Appl Chem]] | ||
}} | }} |
Revision as of 18:59, 28 December 2018
Description
Within the system boundaries, irreversible internal flows of heat and matter along gradients or internal transformations (chemical reactions) contribute to the internal entropy production, diS. In contrast, external flows, Ie, of heat, work and matter proceed reversibly across the system boundaries (of zero thickness).
Abbreviation: Ii [MUยทs-1]
Reference: Gnaiger_1993_Pure Appl Chem
MitoPedia concepts:
MiP concept,
Ergodynamics