Generating interstitial water within the persisting tetrahedral H-bond network explains density increase upon compressing liquid water

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dc.contributor.authorFörster, Mirko
dc.contributor.authorUkoji, Nnanna
dc.contributor.authorSahle, Christoph J.
dc.contributor.authorNiskanen, Johannes
dc.contributor.authorSakrowski, Robin
dc.contributor.authorSurmeier, Göran
dc.contributor.authorWeis, Christopher
dc.contributor.authorIrifune, Tetsuo
dc.contributor.authorImoto, Sho
dc.contributor.authorYavas, Hasan
dc.contributor.authorHuotari, Simo
dc.contributor.authorMarx, Dominik
dc.contributor.authorSternemann, Christian
dc.contributor.authorTse, John S.
dc.contributor.organizationfi=materiaalitutkimuksen laboratorio|en=Materials Research Laboratory|
dc.contributor.organization-code1.2.246.10.2458963.20.15561262450
dc.converis.publication-id457889120
dc.converis.urlhttps://research.utu.fi/converis/portal/Publication/457889120
dc.date.accessioned2025-08-28T02:20:14Z
dc.date.available2025-08-28T02:20:14Z
dc.description.abstract<p>Despite its ubiquitous nature, the atomic structure of water in its liquid state is still controversially debated. We use a combination of X-ray Raman scattering spectroscopy in conjunction with ab initio and path integral molecular dynamics simulations to study the local atomic and electronic structure of water under high pressure conditions. Systematically increasing fingerprints of non-hydrogen-bonded H2O molecules in the first hydration shell are identified in the experimental and computational oxygen K-edge excitation spectra. This provides evidence for a compaction mechanism in terms of a continuous collapse of the second hydration shell with increasing pressure via generation of interstitial water within locally tetrahedral hydrogen-bonding environments.</p>
dc.identifier.eissn1091-6490
dc.identifier.jour-issn0027-8424
dc.identifier.olddbid208946
dc.identifier.oldhandle10024/191973
dc.identifier.urihttps://www.utupub.fi/handle/11111/36337
dc.identifier.urlhttps://doi.org/10.1073/pnas.2403662121
dc.identifier.urnURN:NBN:fi-fe2025082788154
dc.language.isoen
dc.okm.affiliatedauthorNiskanen, Johannes
dc.okm.discipline114 Physical sciencesen_GB
dc.okm.discipline116 Chemical sciencesen_GB
dc.okm.discipline114 Fysiikkafi_FI
dc.okm.discipline116 Kemiafi_FI
dc.okm.internationalcopublicationinternational co-publication
dc.okm.internationalityInternational publication
dc.okm.typeA1 ScientificArticle
dc.publisherNational Academy of Sciences
dc.publisher.countryUnited Statesen_GB
dc.publisher.countryYhdysvallat (USA)fi_FI
dc.publisher.country-codeUS
dc.relation.articlenumbere2403662121
dc.relation.doi10.1073/pnas.2403662121
dc.relation.ispartofjournalProceedings of the National Academy of Sciences of the United States of America
dc.relation.issue39
dc.relation.volume121
dc.source.identifierhttps://www.utupub.fi/handle/10024/191973
dc.titleGenerating interstitial water within the persisting tetrahedral H-bond network explains density increase upon compressing liquid water
dc.year.issued2024

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