Long range electrostatic forces in ionic liquids

Ionic liquids are pure salts that are liquid under ambient conditions. As liquids composed solely of ions, the scientific consensus has been that ionic liquids have exceedingly high ionic strengths and thus very short Debye screening lengths. However, several recent experiments from laboratories aro...

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Published inChemical communications (Cambridge, England) Vol. 53; no. 7; pp. 1214 - 1224
Main Authors Gebbie, Matthew A, Smith, Alexander M, Dobbs, Howard A, Lee, Alpha A, Warr, Gregory G, Banquy, Xavier, Valtiner, Markus, Rutland, Mark W, Israelachvili, Jacob N, Perkin, Susan, Atkin, Rob
Format Journal Article
LanguageEnglish
Published England 2017
Subjects
chemical reactions
dielectric constant
Electrolytes
electrostatic interactions
Electrostatics
energy
force
Inorganic salts
ion
ionic liquid
Ionic liquids
ionic strength
ions
Liquids
nanomaterial
Origins
physics
screening
Self assembly
Solvents
static electricity
surface property
Online AccessGet full text
ISSN1359-7345
1364-548X
1364-548X
DOI10.1039/c6cc08820a

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Abstract Ionic liquids are pure salts that are liquid under ambient conditions. As liquids composed solely of ions, the scientific consensus has been that ionic liquids have exceedingly high ionic strengths and thus very short Debye screening lengths. However, several recent experiments from laboratories around the world have reported data for the approach of two surfaces separated by ionic liquids which revealed remarkable long range forces that appear to be electrostatic in origin. Evidence has accumulated demonstrating long range surface forces for several different combinations of ionic liquids and electrically charged surfaces, as well as for concentrated mixtures of inorganic salts in solvent. The original interpretation of these forces, that ionic liquids could be envisioned as "dilute electrolytes," was controversial, and the origin of long range forces in ionic liquids remains the subject of discussion. Here we seek to collate and examine the evidence for long range surface forces in ionic liquids, identify key outstanding questions, and explore possible mechanisms underlying the origin of these long range forces. Long range surface forces in ionic liquids and other highly concentrated electrolytes hold diverse implications from designing ionic liquids for energy storage applications to rationalizing electrostatic correlations in biological self-assembly. Experimental evidence for long range surface forces in ionic liquids is collated and examined, key outstanding questions are identified, and possible mechanisms underpinning these long range forces are explored.
AbstractList Ionic liquids are pure salts that are liquid under ambient conditions. As liquids composed solely of ions, the scientific consensus has been that ionic liquids have exceedingly high ionic strengths and thus very short Debye screening lengths. However, several recent experiments from laboratories around the world have reported data for the approach of two surfaces separated by ionic liquids which revealed remarkable long range forces that appear to be electrostatic in origin. Evidence has accumulated demonstrating long range surface forces for several different combinations of ionic liquids and electrically charged surfaces, as well as for concentrated mixtures of inorganic salts in solvent. The original interpretation of these forces, that ionic liquids could be envisioned as "dilute electrolytes," was controversial, and the origin of long range forces in ionic liquids remains the subject of discussion. Here we seek to collate and examine the evidence for long range surface forces in ionic liquids, identify key outstanding questions, and explore possible mechanisms underlying the origin of these long range forces. Long range surface forces in ionic liquids and other highly concentrated electrolytes hold diverse implications from designing ionic liquids for energy storage applications to rationalizing electrostatic correlations in biological self-assembly. Experimental evidence for long range surface forces in ionic liquids is collated and examined, key outstanding questions are identified, and possible mechanisms underpinning these long range forces are explored.
Ionic liquids are pure salts that are liquid under ambient conditions. As liquids composed solely of ions, the scientific consensus has been that ionic liquids have exceedingly high ionic strengths and thus very short Debye screening lengths. However, several recent experiments from laboratories around the world have reported data for the approach of two surfaces separated by ionic liquids which revealed remarkable long range forces that appear to be electrostatic in origin. Evidence has accumulated demonstrating long range surface forces for several different combinations of ionic liquids and electrically charged surfaces, as well as for concentrated mixtures of inorganic salts in solvent. The original interpretation of these forces, that ionic liquids could be envisioned as "dilute electrolytes," was controversial, and the origin of long range forces in ionic liquids remains the subject of discussion. Here we seek to collate and examine the evidence for long range surface forces in ionic liquids, identify key outstanding questions, and explore possible mechanisms underlying the origin of these long range forces. Long range surface forces in ionic liquids and other highly concentrated electrolytes hold diverse implications from designing ionic liquids for energy storage applications to rationalizing electrostatic correlations in biological self-assembly.
Author Rutland, Mark W
Valtiner, Markus
Atkin, Rob
Smith, Alexander M
Warr, Gregory G
Lee, Alpha A
Israelachvili, Jacob N
Dobbs, Howard A
Banquy, Xavier
Gebbie, Matthew A
Perkin, Susan
AuthorAffiliation The University of Sydney
Priority Research Centre for Advanced Fluid Interfaces
Stanford University
Newcastle Institute for Energy and Resources
Surface and Corrosion Science
F11
SP Chemistry Materials and Surfaces
Physical & Theoretical Chemistry Laboratory
University of California
School of Engineering and Applied Sciences
Faculty of Pharmacy
KTH Royal Institute of Technology
Harvard University
Geballe Laboratory for Advanced Materials
School of Chemistry
Department of Chemistry
The University of Newcastle
Interface Chemistry and Surface Engineering
Department of Chemical Engineering
University of Oxford
Max Planck Institut fur Eisenforschung GmbH
Universite de Montreal
AuthorAffiliation_xml – name: Department of Chemical Engineering
– name: Surface and Corrosion Science
– name: Department of Chemistry
– name: Interface Chemistry and Surface Engineering
– name: Geballe Laboratory for Advanced Materials
– name: The University of Newcastle
– name: School of Engineering and Applied Sciences
– name: Newcastle Institute for Energy and Resources
– name: Max Planck Institut fur Eisenforschung GmbH
– name: Physical & Theoretical Chemistry Laboratory
– name: The University of Sydney
– name: Faculty of Pharmacy
– name: Stanford University
– name: University of Oxford
– name: F11
– name: University of California
– name: KTH Royal Institute of Technology
– name: SP Chemistry Materials and Surfaces
– name: Priority Research Centre for Advanced Fluid Interfaces
– name: Harvard University
– name: School of Chemistry
– name: Universite de Montreal
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  givenname: Matthew A
  surname: Gebbie
  fullname: Gebbie, Matthew A
– sequence: 2
  givenname: Alexander M
  surname: Smith
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– sequence: 3
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  surname: Dobbs
  fullname: Dobbs, Howard A
– sequence: 4
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  surname: Lee
  fullname: Lee, Alpha A
– sequence: 5
  givenname: Gregory G
  surname: Warr
  fullname: Warr, Gregory G
– sequence: 6
  givenname: Xavier
  surname: Banquy
  fullname: Banquy, Xavier
– sequence: 7
  givenname: Markus
  surname: Valtiner
  fullname: Valtiner, Markus
– sequence: 8
  givenname: Mark W
  surname: Rutland
  fullname: Rutland, Mark W
– sequence: 9
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  surname: Israelachvili
  fullname: Israelachvili, Jacob N
– sequence: 10
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  surname: Perkin
  fullname: Perkin, Susan
– sequence: 11
  givenname: Rob
  surname: Atkin
  fullname: Atkin, Rob
BackLink https://www.ncbi.nlm.nih.gov/pubmed/28000809$$D View this record in MEDLINE/PubMed
https://urn.kb.se/resolve?urn=urn:nbn:se:kth:diva-204710$$DView record from Swedish Publication Index
https://urn.kb.se/resolve?urn=urn:nbn:se:ri:diva-30985$$DView record from Swedish Publication Index
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Snippet Ionic liquids are pure salts that are liquid under ambient conditions. As liquids composed solely of ions, the scientific consensus has been that ionic liquids...
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SubjectTerms chemical reactions
dielectric constant
Electrolytes
electrostatic interactions
Electrostatics
energy
force
Inorganic salts
ion
ionic liquid
Ionic liquids
ionic strength
ions
Liquids
nanomaterial
Origins
physics
screening
Self assembly
Solvents
static electricity
surface property
Title Long range electrostatic forces in ionic liquids
URI https://www.ncbi.nlm.nih.gov/pubmed/28000809
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