Difference between revisions of "Solubility"
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|abbr=''S''<sub>G</sub> | |abbr=''S''<sub>G</sub> | ||
|description=The '''solubility''' of a gas, ''S''<sub>G</sub>, is defined as concentration divided by partial pressure, ''S''<sub>G</sub> = ''c''<sub>G</sub>·''p''<sub>G</sub><sup>-1</sup>. | |description=The '''solubility''' of a gas, ''S''<sub>G</sub>, is defined as concentration divided by partial pressure, ''S''<sub>G</sub> = ''c''<sub>G</sub>·''p''<sub>G</sub><sup>-1</sup>. | ||
|info=[[Hitchman 1983 POS Membrane]] | |info=[[Hitchman 1983 POS Membrane |Hitchman and Gnaiger 1983]] | ||
}} | }} | ||
:::: The solubility of a gas ([[Hitchman 1983 POS Membrane |Hitchman and Gnaiger 1983]]) — sometimes called the 'solubility coefficient' — is related to the classical Bunsen absorption coefficient, ''α'' (see [[Forstner 1983 POS |Forstner and Gnaiger 1983]]). | :::: The solubility of a gas ([[Hitchman 1983 POS Membrane |Hitchman and Gnaiger 1983]]) — sometimes called the 'solubility coefficient' — is related to the classical Bunsen absorption coefficient, ''α'' (see [[Forstner 1983 POS |Forstner and Gnaiger 1983]]). ''S''<sub>G</sub> has the dimension of molar amount of the gas per volume of the solution per partial pressure of the gas, ''α'' has the dimension of volume of the gas ([[STPD]]) per volume of the solution per partial pressure of the gas. | ||
:::: The inverse of ''S''<sub>G</sub> is related to the activity coefficient (concentration basis) of the gas (see [[Activity]]), | :::: The inverse of ''S''<sub>G</sub> is related to the activity coefficient (concentration basis) of the gas (see [[Activity]]), |
Latest revision as of 23:33, 16 February 2020
Description
The solubility of a gas, SG, is defined as concentration divided by partial pressure, SG = cG·pG-1.
Abbreviation: SG
Reference: Hitchman and Gnaiger 1983
- The solubility of a gas (Hitchman and Gnaiger 1983) — sometimes called the 'solubility coefficient' — is related to the classical Bunsen absorption coefficient, α (see Forstner and Gnaiger 1983). SG has the dimension of molar amount of the gas per volume of the solution per partial pressure of the gas, α has the dimension of volume of the gas (STPD) per volume of the solution per partial pressure of the gas.
- The inverse of SG is related to the activity coefficient (concentration basis) of the gas (see Activity),
γB = SG-1·c°/p°
- Bioblast links: Concentration and pressure - >>>>>>> - Click on [Expand] or [Collapse] - >>>>>>>
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- Solubility = concentration/pressure
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References
- Forstner H, Gnaiger E (1983) Calculation of equilibrium oxygen concentration. In: Polarographic Oxygen Sensors. Aquatic and Physiological Applications. Gnaiger E, Forstner H (eds), Springer, Berlin, Heidelberg, New York:321-33. - »Bioblast link«
- Hitchman ML, Gnaiger E (1983) A thermodynamic consideration of permeability coefficients of membranes. In: Polarographic Oxygen Sensors. Aquatic and Physiological Applications. Gnaiger E, Forstner H (eds), Springer, Berlin, Heidelberg, New York:31-6. - »Bioblast link«
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