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Simulation of ion transport through poly(ethylene oxide) loaded with lithium perchlorate
2009
journal article
article
Journal
Materials Science Poland
Author
Munn R. W.
Eilmes Andrzej
Scarle S.
Sterzel Mariusz
Volume
27
Number
3
Pages
637-647
ISSN
2083-1331
eISSN
2083-134X
Keywords in English
ion transport simulation
lithium perchlorate
poly(ethylene oxide)
tungsten oxide
electrochromism
Access date
2019-07-16
Remarks
Bibliogr. s. 646-647.
Language
English
Journal language
English
Abstract in English
A hierarchical approach is used to simulate lithium ion motion through poly(ethylene oxide) loaded with lithium perchlorate, alone and with a tungsten oxide (WO3) interface to model an electrochromic smart window assembly. The structure of the polymer is simulated using commercial software. Relaxation of the polymer is allowed on a lattice on which the lithium ions move as a lattice gas. Polarization and van der Waals energy changes are calculated for an added lithium ion at each lattice point. The structure and energy are also calculated in the presence of the WO3 interface. Ion transport is simulated in a kinetic Monte Carlo method, with and without an electric field. During runs at 300 K without the WO3 interface, with a field the lithium ions move 35 Å along it and 3–7 Å across it but without a field they move 2–5 Å; these distances vary with temperature as expected for activated hopping. Ions explore their immediate neighbourhood, occasionally jumping to an adjacent neighbourhood along, across or sometimes against the field, thus circumventing regions where transport is hindered. With the WO3, the lithium ions tend to accumulate at the interface, producing a repulsive potential that reduces ion movement.
Affiliation
Wydział Chemii : Zakład Metod Obliczeniowych Chemii
| dc.abstract.en | A hierarchical approach is used to simulate lithium ion motion through poly(ethylene oxide) loaded with lithium perchlorate, alone and with a tungsten oxide (WO3) interface to model an electrochromic smart window assembly. The structure of the polymer is simulated using commercial software. Relaxation of the polymer is allowed on a lattice on which the lithium ions move as a lattice gas. Polarization and van der Waals energy changes are calculated for an added lithium ion at each lattice point. The structure and energy are also calculated in the presence of the WO3 interface. Ion transport is simulated in a kinetic Monte Carlo method, with and without an electric field. During runs at 300 K without the WO3 interface, with a field the lithium ions move 35 Å along it and 3–7 Å across it but without a field they move 2–5 Å; these distances vary with temperature as expected for activated hopping. Ions explore their immediate neighbourhood, occasionally jumping to an adjacent neighbourhood along, across or sometimes against the field, thus circumventing regions where transport is hindered. With the WO3, the lithium ions tend to accumulate at the interface, producing a repulsive potential that reduces ion movement. | pl |
| dc.affiliation | Wydział Chemii : Zakład Metod Obliczeniowych Chemii | pl |
| dc.contributor.author | Munn, R. W. | pl |
| dc.contributor.author | Eilmes, Andrzej - 127871 | pl |
| dc.contributor.author | Scarle, S. | pl |
| dc.contributor.author | Sterzel, Mariusz | pl |
| dc.date.accession | 2019-07-16 | pl |
| dc.date.accessioned | 2019-07-16T08:38:54Z | |
| dc.date.available | 2019-07-16T08:38:54Z | |
| dc.date.issued | 2009 | pl |
| dc.date.openaccess | 0 | |
| dc.description.accesstime | w momencie opublikowania | |
| dc.description.additional | Bibliogr. s. 646-647. | pl |
| dc.description.number | 3 | pl |
| dc.description.physical | 637-647 | pl |
| dc.description.version | ostateczna wersja wydawcy | |
| dc.description.volume | 27 | pl |
| dc.identifier.eissn | 2083-134X | pl |
| dc.identifier.issn | 2083-1331 | pl |
| dc.identifier.project | ROD UJ / OP | pl |
| dc.identifier.uri | https://ruj.uj.edu.pl/xmlui/handle/item/79174 | |
| dc.identifier.weblink | http://www.materialsscience.pwr.wroc.pl/bi/vol27no3/articles/ms_04_munn.pdf | pl |
| dc.language | eng | pl |
| dc.language.container | eng | pl |
| dc.rights | Udzielam licencji. Uznanie autorstwa - Użycie niekomercyjne - Bez utworów zależnych 3.0 | * |
| dc.rights.licence | CC-BY-NC-ND | |
| dc.rights.uri | http://creativecommons.org/licenses/by-nc-nd/3.0/legalcode | * |
| dc.share.type | otwarte czasopismo | |
| dc.subject.en | ion transport simulation | pl |
| dc.subject.en | lithium perchlorate | pl |
| dc.subject.en | poly(ethylene oxide) | pl |
| dc.subject.en | tungsten oxide | pl |
| dc.subject.en | electrochromism | pl |
| dc.subtype | Article | pl |
| dc.title | Simulation of ion transport through poly(ethylene oxide) loaded with lithium perchlorate | pl |
| dc.title.journal | Materials Science Poland | pl |
| dc.type | JournalArticle | pl |
| dspace.entity.type | Publication |
dc.abstract.enpl
A hierarchical approach is used to simulate lithium ion motion through poly(ethylene oxide) loaded
with lithium perchlorate, alone and with a tungsten oxide (WO3) interface to model an electrochromic
smart window assembly. The structure of the polymer is simulated using commercial software. Relaxation of the polymer is allowed on a lattice on which the lithium ions move as a lattice gas. Polarization
and van der Waals energy changes are calculated for an added lithium ion at each lattice point. The structure and energy are also calculated in the presence of the WO3 interface. Ion transport is simulated in a
kinetic Monte Carlo method, with and without an electric field. During runs at 300 K without the WO3
interface, with a field the lithium ions move 35 Å along it and 3–7 Å across it but without a field they
move 2–5 Å; these distances vary with temperature as expected for activated hopping. Ions explore their
immediate neighbourhood, occasionally jumping to an adjacent neighbourhood along, across or sometimes against the field, thus circumventing regions where transport is hindered. With the WO3, the lithium
ions tend to accumulate at the interface, producing a repulsive potential that reduces ion movement. dc.affiliationpl
Wydział Chemii : Zakład Metod Obliczeniowych Chemii dc.contributor.authorpl
Munn, R. W. dc.contributor.authorpl
Eilmes, Andrzej - 127871 dc.contributor.authorpl
Scarle, S. dc.contributor.authorpl
Sterzel, Mariusz dc.date.accessionpl
2019-07-16 dc.date.accessioned
2019-07-16T08:38:54Z dc.date.available
2019-07-16T08:38:54Z dc.date.issuedpl
2009 dc.date.openaccess
0 dc.description.accesstime
w momencie opublikowania dc.description.additionalpl
Bibliogr. s. 646-647. dc.description.numberpl
3 dc.description.physicalpl
637-647 dc.description.version
ostateczna wersja wydawcy dc.description.volumepl
27 dc.identifier.eissnpl
2083-134X dc.identifier.issnpl
2083-1331 dc.identifier.projectpl
ROD UJ / OP dc.identifier.uri
https://ruj.uj.edu.pl/xmlui/handle/item/79174 dc.identifier.weblinkpl
http://www.materialsscience.pwr.wroc.pl/bi/vol27no3/articles/ms_04_munn.pdf dc.languagepl
eng dc.language.containerpl
eng dc.rights*
Udzielam licencji. Uznanie autorstwa - Użycie niekomercyjne - Bez utworów zależnych 3.0 dc.rights.licence
CC-BY-NC-ND dc.rights.uri*
http://creativecommons.org/licenses/by-nc-nd/3.0/legalcode dc.share.type
otwarte czasopismo dc.subject.enpl
ion transport simulation dc.subject.enpl
lithium perchlorate dc.subject.enpl
poly(ethylene oxide) dc.subject.enpl
tungsten oxide dc.subject.enpl
electrochromism dc.subtypepl
Article dc.titlepl
Simulation of ion transport through poly(ethylene oxide) loaded with lithium perchlorate dc.title.journalpl
Materials Science Poland dc.typepl
JournalArticle dspace.entity.type
Publication Affiliations
No affiliation
Munn, R. W.
Eilmes, Andrzej
Scarle, S.
Sterzel, Mariusz
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