Development of a rationale for decoupling osmotic coefficient of electrolytes into electrostatic and nonelectrostatic contributions

In this work, a method has been developed to decouple the electrostatic and the nonelectrostatic contributions to the osmotic coefficient. The observation, that the osmotic coefficient-molality plot exhibits a linear region over a significant range of concentration, allows estimation of the primary...

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Published in:Geophysical Research Letters
Main Authors: SAHU, J, JUVEKAR, VA
Format: Article in Journal/Newspaper
Language:English
Published: ELSEVIER SCIENCE BV 2018
Subjects:
Osmotic coefficient
Electrostatic interaction
Nonelectrostatic interaction
Primary hydration number
Limiting secondary hydration number
CONCENTRATED AQUEOUS-ELECTROLYTE
LIQUID-VAPOR-EQUILIBRIUM
LOCAL COMPOSITION MODEL
EXCESS GIBBS ENERGY
THERMODYNAMIC PROPERTIES
HYDRATION NUMBERS
298.15 K
HYGROMETRIC DETERMINATION
OCEAN ACIDIFICATION
MAGNETIC-RESONANCE
Ocean acidification
Online Access:http://dspace.library.iitb.ac.in/xmlui/handle/100/23307
https://doi.org/10.1002/2014GL061047
id ftiitbombay:oai:dsapce.library.iitb.ac.in:100/23307
record_format openpolar
spelling ftiitbombay:oai:dsapce.library.iitb.ac.in:100/23307 2023-05-15T17:52:08+02:00 Development of a rationale for decoupling osmotic coefficient of electrolytes into electrostatic and nonelectrostatic contributions SAHU, J JUVEKAR, VA 2018 http://dspace.library.iitb.ac.in/xmlui/handle/100/23307 https://doi.org/10.1002/2014GL061047 English eng ELSEVIER SCIENCE BV FLUID PHASE EQUILIBRIA,460()57-68 0378-3812;1879-0224 http://dx.doi.org/10.1002/2014GL061047 http://dspace.library.iitb.ac.in/xmlui/handle/100/23307 Osmotic coefficient Electrostatic interaction Nonelectrostatic interaction Primary hydration number Limiting secondary hydration number CONCENTRATED AQUEOUS-ELECTROLYTE LIQUID-VAPOR-EQUILIBRIUM LOCAL COMPOSITION MODEL EXCESS GIBBS ENERGY THERMODYNAMIC PROPERTIES HYDRATION NUMBERS 298.15 K HYGROMETRIC DETERMINATION OCEAN ACIDIFICATION MAGNETIC-RESONANCE Article 2018 ftiitbombay https://doi.org/10.1002/2014GL061047 2021-06-03T17:48:43Z In this work, a method has been developed to decouple the electrostatic and the nonelectrostatic contributions to the osmotic coefficient. The observation, that the osmotic coefficient-molality plot exhibits a linear region over a significant range of concentration, allows estimation of the primary hydration number of electrolytes and also to hypothesize that the primary hydration number does not depend on electrolyte concentration. The estimated value of the primary hydration number agrees well with that obtained using NMR spectroscopy and exhibits correct dependence on temperature. It is also shown that in a mixture of electrolytes, each electrolyte retains its own primary hydration number irrespective of the presence of the other electrolytes. The estimate of the primary hydration number allows us to determine the nonelectrostatic contribution to the osmotic coefficient for the single and the mixed electrolytes over the entire range of electrolyte concentration. Subtraction of this contribution from the osmotic coefficient yields the electrostatic contribution. The secondary hydration number, which is responsible for modulating electrostatic interaction, attains a constant value beyond the electrostatic screening limit and at a fixed temperature, this value is found to be independent of the type of electrolyte. The sum of the primary hydration number and the limiting secondary hydration number agrees well with the hydration number estimated using the extended X-ray absorption fine structure spectroscopy. The most important contribution of this work is the isolation of the electrostatic contribution to the osmotic coefficient of solutions of single and mixed electrolytes. The electrostatic interaction is shown to much stronger than that predicted by the extended Debye-FRickel theory, which points to a need for revision of the existing theories for electrostatics of concentrated electrolytes. The electrostatic contribution estimated using the present method, for both single as well as mixed electrolytes, would provide the basis for validation of the revised theories. (C) 2017 Elsevier B.V. All rights reserved. Article in Journal/Newspaper Ocean acidification DSpace@IIT Bombay (Indian Institute of Technology) Geophysical Research Letters 41 17 6207 6212
institution Open Polar
collection DSpace@IIT Bombay (Indian Institute of Technology)
op_collection_id ftiitbombay
language English
topic Osmotic coefficient
Electrostatic interaction
Nonelectrostatic interaction
Primary hydration number
Limiting secondary hydration number
CONCENTRATED AQUEOUS-ELECTROLYTE
LIQUID-VAPOR-EQUILIBRIUM
LOCAL COMPOSITION MODEL
EXCESS GIBBS ENERGY
THERMODYNAMIC PROPERTIES
HYDRATION NUMBERS
298.15 K
HYGROMETRIC DETERMINATION
OCEAN ACIDIFICATION
MAGNETIC-RESONANCE
spellingShingle Osmotic coefficient
Electrostatic interaction
Nonelectrostatic interaction
Primary hydration number
Limiting secondary hydration number
CONCENTRATED AQUEOUS-ELECTROLYTE
LIQUID-VAPOR-EQUILIBRIUM
LOCAL COMPOSITION MODEL
EXCESS GIBBS ENERGY
THERMODYNAMIC PROPERTIES
HYDRATION NUMBERS
298.15 K
HYGROMETRIC DETERMINATION
OCEAN ACIDIFICATION
MAGNETIC-RESONANCE
SAHU, J
JUVEKAR, VA
Development of a rationale for decoupling osmotic coefficient of electrolytes into electrostatic and nonelectrostatic contributions
topic_facet Osmotic coefficient
Electrostatic interaction
Nonelectrostatic interaction
Primary hydration number
Limiting secondary hydration number
CONCENTRATED AQUEOUS-ELECTROLYTE
LIQUID-VAPOR-EQUILIBRIUM
LOCAL COMPOSITION MODEL
EXCESS GIBBS ENERGY
THERMODYNAMIC PROPERTIES
HYDRATION NUMBERS
298.15 K
HYGROMETRIC DETERMINATION
OCEAN ACIDIFICATION
MAGNETIC-RESONANCE
description In this work, a method has been developed to decouple the electrostatic and the nonelectrostatic contributions to the osmotic coefficient. The observation, that the osmotic coefficient-molality plot exhibits a linear region over a significant range of concentration, allows estimation of the primary hydration number of electrolytes and also to hypothesize that the primary hydration number does not depend on electrolyte concentration. The estimated value of the primary hydration number agrees well with that obtained using NMR spectroscopy and exhibits correct dependence on temperature. It is also shown that in a mixture of electrolytes, each electrolyte retains its own primary hydration number irrespective of the presence of the other electrolytes. The estimate of the primary hydration number allows us to determine the nonelectrostatic contribution to the osmotic coefficient for the single and the mixed electrolytes over the entire range of electrolyte concentration. Subtraction of this contribution from the osmotic coefficient yields the electrostatic contribution. The secondary hydration number, which is responsible for modulating electrostatic interaction, attains a constant value beyond the electrostatic screening limit and at a fixed temperature, this value is found to be independent of the type of electrolyte. The sum of the primary hydration number and the limiting secondary hydration number agrees well with the hydration number estimated using the extended X-ray absorption fine structure spectroscopy. The most important contribution of this work is the isolation of the electrostatic contribution to the osmotic coefficient of solutions of single and mixed electrolytes. The electrostatic interaction is shown to much stronger than that predicted by the extended Debye-FRickel theory, which points to a need for revision of the existing theories for electrostatics of concentrated electrolytes. The electrostatic contribution estimated using the present method, for both single as well as mixed electrolytes, would provide the basis for validation of the revised theories. (C) 2017 Elsevier B.V. All rights reserved.
format Article in Journal/Newspaper
author SAHU, J
JUVEKAR, VA
author_facet SAHU, J
JUVEKAR, VA
author_sort SAHU, J
title Development of a rationale for decoupling osmotic coefficient of electrolytes into electrostatic and nonelectrostatic contributions
title_short Development of a rationale for decoupling osmotic coefficient of electrolytes into electrostatic and nonelectrostatic contributions
title_full Development of a rationale for decoupling osmotic coefficient of electrolytes into electrostatic and nonelectrostatic contributions
title_fullStr Development of a rationale for decoupling osmotic coefficient of electrolytes into electrostatic and nonelectrostatic contributions
title_full_unstemmed Development of a rationale for decoupling osmotic coefficient of electrolytes into electrostatic and nonelectrostatic contributions
title_sort development of a rationale for decoupling osmotic coefficient of electrolytes into electrostatic and nonelectrostatic contributions
publisher ELSEVIER SCIENCE BV
publishDate 2018
url http://dspace.library.iitb.ac.in/xmlui/handle/100/23307
https://doi.org/10.1002/2014GL061047
genre Ocean acidification
genre_facet Ocean acidification
op_relation FLUID PHASE EQUILIBRIA,460()57-68
0378-3812;1879-0224
http://dx.doi.org/10.1002/2014GL061047
http://dspace.library.iitb.ac.in/xmlui/handle/100/23307
op_doi https://doi.org/10.1002/2014GL061047
container_title Geophysical Research Letters
container_volume 41
container_issue 17
container_start_page 6207
op_container_end_page 6212
_version_ 1766159474839519232

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