Advancement: Difference between revisions
No edit summary |
No edit summary |
||
| Line 4: | Line 4: | ||
|info=[[Gnaiger_1993_Pure Appl Chem]] | |info=[[Gnaiger_1993_Pure Appl Chem]] | ||
}} | }} | ||
Communicated by [[Gnaiger E]] 2018-10-15 | |||
{{MitoPedia concepts | {{MitoPedia concepts | ||
|mitopedia concept=MiP concept, Ergodynamics | |mitopedia concept=MiP concept, Ergodynamics | ||
}} | }} | ||
Revision as of 15:24, 15 October 2018
- high-resolution terminology - matching measurements at high-resolution
Advancement
Description
In an isomorphic analysis, any form of flow is the advancement of a process per unit of time, expressed in a specific motive unit [MUβs-1], e.g., ampere for electric flow or current [Aβ‘Cβs-1], watt for heat flow [Wβ‘Jβs-1], and for chemical flow the unit is [molβs-1]. The corresponding isomorphic forces are the partial exergy (Gibbs energy) changes per advancement [JβMU-1], expressed in volt for electric force [Vβ‘JβC-1], dimensionless for thermal force, and for chemical force the unit is [Jβmol-1], which deserves a specific acronym ([Jol]) comparable to volt. For chemical processes of reaction and diffusion, the advancement is the amount of motive substance [mol]. The concept was originally introduced by De Donder. Central to the concept of advancement is the stoichiometric number, Ξ½X, associated with each motive component X (transformant [1]).
Abbreviation: dtrΞΎ
Reference: Gnaiger_1993_Pure Appl Chem
Communicated by Gnaiger E 2018-10-15
MitoPedia concepts: MiP concept, Ergodynamics
