Dynamic Buffer Capacities in Redox Systems

Michałowska-Kaczmarczyk, Anna Maria; Spórna‐Kucab, Aneta; Michałowski, Tadeusz

doi:10.21767/2471-8084.100039

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Cited by 8 publications

(1 citation statement)

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“…Some kinetic effects involved with organic compounds can also be tested [39]. The dynamic buffer capacities [40] in the form analogous to dynamic buffer capacity in acid-base systems [41,42] were also formulated. From the GATES/GEB [1,[3][4][5][6][7][8][10][11][12][13][14][15][16][43][44][45][46] viewpoint, the terms: oxidation number, oxidant and reductant, equivalent mass [8] are derivative terms [47], not necessary (not applicable) for considerations on a redox system.…”

Section: Final Commentsmentioning

confidence: 99%

The Distinguishing Role of 2.f(O) - f(H) in Electrolytic Systems

Kaczmarczyk

2018

BJSTR

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Section: Final Commentsmentioning

confidence: 99%

The Distinguishing Role of 2.f(O) - f(H) in Electrolytic Systems

Kaczmarczyk

2018

BJSTR

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The Balance 2∙f (O) – f (H) as a Cornerstone in Formulation of Electrolytic Systems

Michałowska-Kaczmarczyk

Michałowski

2018

JNDC

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The Generalized Electron Balance (GEB) concept, related to electrolytic redox systems, is considered according to principles of Generalized Approach to Electrolytic Systems (GATES). Two equivalent Approaches (I and II) to GEB are presented. The Approach I, when perceived in convention of the card game, is based on the common pool of electrons as money, introduced by electron-active elements, named as players; electron-non-active elements are called there as fans. The GEB obtained according to Approach II results from the linear combination f12 = 2∙f(O) – f(H) of elemental balances: f1 = f(H) for H, and f2 = f(O) for O. Very important properties of f12 are presented here in details, and illustrated by a redox system where comproportion- ation reactions occur

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Formulation of Isohydricity Conditions in Acid-Base systems - A Review

Michałowska-Kaczmarczyk

Michałowski

2020

JNDC

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The isohydricity conditions are formulated for D+T systems composed of titrand D and titrant T, mixed according to titrimetric mode; only acid-base equilibria are involved there. The original method of dissociation constants determination, based on the isohydricity principle, is presented and confirmed experimentally. The pH titrations in the system of isohydric solutions are also put in context with conductometric titrations.

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Dynamic Buffer Capacities in Redox Systems

Cited by 8 publications

References 31 publications

The Distinguishing Role of 2.f(O) - f(H) in Electrolytic Systems

The Distinguishing Role of 2.f(O) - f(H) in Electrolytic Systems

The Balance 2∙f (O) – f (H) as a Cornerstone in Formulation of Electrolytic Systems

Formulation of Isohydricity Conditions in Acid-Base systems - A Review

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