Journal article
Water Networks within Metal Organic Nanotubes: Assessment of Techniques to Understand Structure and Properties
European journal of inorganic chemistry, Vol.27(33), e202400327
11/21/2024
DOI: 10.1002/ejic.202400327
Appears in UI Libraries Support Open Access
Abstract
Hybrid materials, such as metal organic nanotubes (MONTs) can possess nanoconfined water molecules within their pore space and the overall behavior of the water within the material may be tuned based upon interactions with the inner channel walls. We have previously developed a range of methods (electron density mapping, kinetic models, and water interaction enthalpies) to evaluate water behavior under nanoconfinement using a uranium‐based metal organic nanotube (UMONT) but have not explored their applicability across a range of materials. In the current study, we test our methodologies on two additional MONT materials (LaMONT and Cu‐LaMONT) to determine if the techniques can be utilized in other systems to predict behavior within complex hybrid materials. In addition, we explored how to use Hirshfeld surface maps generated by the CrystalExplorer software in the visualization and prediction of water behavior within complex hybrid materials.
Details
- Title: Subtitle
- Water Networks within Metal Organic Nanotubes: Assessment of Techniques to Understand Structure and Properties
- Creators
- Vidumini Suchintha Samarasiri - University of IowaTiron Jahinge - University of Iowa Chemistry UNITED STATES OF AMERICATori Forbes - University of Iowa
- Resource Type
- Journal article
- Publication Details
- European journal of inorganic chemistry, Vol.27(33), e202400327
- Publisher
- Wiley
- DOI
- 10.1002/ejic.202400327
- ISSN
- 1434-1948
- eISSN
- 1099-0682
- Grant note
- National Science Foundation Division of Materials Research
We acknowledge support from the National Science Foundation Division of Materials Research (NSF-DMR15246700).
- Language
- English
- Electronic publication date
- 09/19/2024
- Date published
- 11/21/2024
- Academic Unit
- Chemistry; Civil and Environmental Engineering; Core Research Facilities
- Record Identifier
- 9984719271702771
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