Advancement per volume: Difference between revisions

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Advancement per volume

Description

Advancement per volume or volume-specific advancement, d_trY [mol∙V^-1], is related to advancement, d_trY = d_trξ∙V^-1, as is the amount of substance per volume, c_i (concentration) [mol∙V^-1], related to amount, c_i = = n_i∙V^-1. Advancement per volume is particularly introduced for chemical reactions, d_rY, where it has the dimension of a concentration. In an open system at steady-state, however, the concentration does not change as the reaction advances. Only in closed systems, specific advancement is the change in concentration divided by the stoichiometric number, Δ_rY = Δc_i/ν_i. In general, Δc_i is replaced by the partial change of concentration, Δ_rc_i, which contributes to the total change of concentration, Δc_i. In open systems at steady-state, Δ_rc_i is compensated by external processes, Δ_extc_i, exerting an effect on the total concentration change, Δc_i = Δ_rc_i + Δ_extc_i = 0.

Abbreviation: d_trY

Reference: Gnaiger_1993_Pure Appl Chem

Application in respirometry

In typical liquid phase reactions the volume of the system does not change during the reaction. When oxygen consumption (ν_O2 = -1 in the chemical reaction) is measured in aqueous solution, then the volume-specific oxygen flux is the time derivative of the advancement of the reaction per volume [1], J_V,O2 = d_rY_O2/dt = d_rξ_O2/dt∙V^-1 [(mol∙s^-1)∙L^-1]. The rate of O₂ concentration change is dc_O2/dt [(mol∙L^-1)∙s^-1], where concentration is c_O2 = n_O2∙V^-1. There is a difference between (1) J_V,O2 [mol∙s^-1∙L^-1] and (2) rate of concentration change [mol∙L^-1∙s^-1]. These merge to a single expression only in a closed system. In open systems, internal transformations (catabolic flux, O₂ consumption) are distinguished from external flux (such as O₂ supply). External fluxes of all substances are zero in closed systems [2].

MitoPedia concepts: Ergodynamics

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 {{MitoPedia
 |abbr=d<sub>tr</sub>''Y''
-|description='''[[Advancement]] per volume''' or volume-specific advancement, d<sub>tr</sub>''Y'', is particularly introduced for chemical reactions, d<sub>r</sub>''Y'', where it has the dimension of a [[concentration]]. In an [[open system]] at steady-state, however, the concentration does not change as the reaction advances. Only in [[closed system]]s, specific advancement is the change in concentration divided by the stoichiometric number, Δ<sub>r</sub>''Y'' = Δ''c<sub>i</sub>''/''ν<sub>i</sub>''. In general, Δ''c<sub>i</sub>'' is replaced by the partial change of concentration, Δ<sub>r</sub>''c<sub>i</sub>'', which contributes to the total change of concentration, Δ''c<sub>i</sub>''. In open systems at steady-state, Δ<sub>r</sub>''c<sub>i</sub>'' is compensated by the external contributions, Δ<sub>ext</sub>''c<sub>i</sub>'', to the total concentration change, Δ''c<sub>i</sub>'' = Δ<sub>r</sub>''c<sub>i</sub>'' + Δ<sub>ext</sub>''c<sub>i</sub>'' = 0.
+|description='''Advancement per volume''' or volume-specific advancement, d<sub>tr</sub>''Y'' [mol∙''V''<sup>-1</sup>], is related to [[advancement]], d<sub>tr</sub>''Y'' = d<sub>tr</sub>''ξ''∙V<sup>-1</sup>, as is the amount of substance per volume, ''c''<sub>i</sub> ([[concentration]]) [mol∙''V''<sup>-1</sup>], related to [[amount]], ''c''<sub>''i''</sub> = = ''n''<sub>i</sub>∙''V''<sup>-1</sup>. Advancement per volume is particularly introduced for chemical reactions, d<sub>r</sub>''Y'', where it has the dimension of a concentration. In an [[open system]] at steady-state, however, the concentration does not change as the reaction advances. Only in [[closed system]]s, specific advancement is the change in concentration divided by the stoichiometric number, Δ<sub>r</sub>''Y'' = Δ''c<sub>i</sub>''/''ν<sub>i</sub>''. In general, Δ''c<sub>i</sub>'' is replaced by the partial change of concentration, Δ<sub>r</sub>''c<sub>i</sub>'', which contributes to the total change of concentration, Δ''c<sub>i</sub>''. In open systems at steady-state, Δ<sub>r</sub>''c<sub>i</sub>'' is compensated by external processes, Δ<sub>ext</sub>''c<sub>i</sub>'', exerting an effect on the total concentration change, Δ''c<sub>i</sub>'' = Δ<sub>r</sub>''c<sub>i</sub>'' + Δ<sub>ext</sub>''c<sub>i</sub>'' = 0.
 |info=[[Gnaiger_1993_Pure Appl Chem]]
 }}
+== Application in respirometry ==
+:::: In typical liquid phase reactions the volume of the system does not change during the reaction. When oxygen consumption (''ν''<sub>O2</sub> = -1 in the chemical reaction) is measured in aqueous solution, then the volume-specific [[oxygen flux]] is the time derivative of the advancement of the reaction per volume [1], ''J''<sub>''V'',O2</sub> = d<sub>r</sub>''Y''<sub>O2</sub>/d''t'' = d<sub>r</sub>''ξ''<sub>O2</sub>/d''t''∙''V''<sup>-1</sup> [(mol∙s<sup>-1</sup>)∙L<sup>-1</sup>]. The rate of O<sub>2</sub> concentration change is d''c''<sub>O2</sub>/d''t'' [(mol∙L<sup>-1</sup>)∙s<sup>-1</sup>], where concentration is ''c''<sub>O2</sub> = ''n''<sub>O2</sub>∙''V''<sup>-1</sup>. There is a difference between (''1'') ''J''<sub>''V'',O2</sub> [mol∙s<sup>-1</sup>∙L<sup>-1</sup>] and (''2'') rate of concentration change [mol∙L<sup>-1</sup>∙s<sup>-1</sup>]. These merge to a single expression only in a closed system. In open systems, internal transformations (catabolic flux, O<sub>2</sub> consumption) are distinguished from external flux (such as O<sub>2</sub> supply). External fluxes of all substances are zero in closed systems [2].
 {{MitoPedia concepts
 |mitopedia concept=Ergodynamics
 }}