Magnetic hybrid materials in liquid crystals
Abstract: The integration of nanoparticles with magnetic, ferroelectric or semiconducting properties into liquid crystals (LCs) has attracted great interest both for fundamental investigations and for technological applications. Here, an overview of hybrid materials based on magnetic nanoparticles (MNPs) and thermotropic LCs is given. After a general introduction to thermotropic LCs and LC-MNP hybrid materials, various preparation methods established by us are presented. The synthesis of shape-(an) isotropic MNPs, their functionalization by tailored (pro) mesogenic ligands with linear or dendritic structures and their integration into LC hosts are discussed. The characterization of the MNPs, (pro) mesogenic ligands and resulting MNP-LC hybrid materials is described to show the influence of MNP functionalization on the MNP-LC interactions including aspects such as colloidal stability and structuring in the LC host. Overall, we show that the physical properties of the hybrid material are significantly influenced not only by the MNPs (i.e., their size, shape and composition) but also by their surface properties (i.e., the structure of the (pro) mesogenic ligands).
- Location
-
Deutsche Nationalbibliothek Frankfurt am Main
- Extent
-
Online-Ressource
- Language
-
Englisch
- Bibliographic citation
-
Magnetic hybrid materials in liquid crystals ; volume:7 ; number:9 ; year:2020 ; pages:1009-1032 ; extent:24
Physical sciences reviews ; 7, Heft 9 (2020), 1009-1032 (gesamt 24)
- Creator
- DOI
-
10.1515/psr-2019-0090
- URN
-
urn:nbn:de:101:1-2022092016324343568639
- Rights
-
Open Access; Der Zugriff auf das Objekt ist unbeschränkt möglich.
- Last update
-
15.08.2025, 7:38 AM CEST
Data provider
Deutsche Nationalbibliothek. If you have any questions about the object, please contact the data provider.
Associated
- Hähsler, Martin
- Appel, Ingo
- Behrens, Silke
Other Objects (12)
Nuclear magnetic resonance of liquid crystals
Nuclear magnetic resonance of liquid crystals
Liquid crystal self-assembly and organic-inorganic hybrid material design
Liquid Crystal Self-Assembly and Organic–Inorganic Hybrid Material Design
Emergent biaxiality in chiral hybrid liquid crystals
Magnetic tuning of liquid crystal dielectric metasurfaces
Hydrogen‐Bonded Siloxane Liquid Crystals for Hybrid Nanomaterials
Dendritic Ligands for Magnetic Suspensions in Liquid Crystals
Wavelength‐Selective Photopolymerization of Hybrid Acrylate‐Oxetane Liquid Crystals
Wavelength‐Selective Photopolymerization of Hybrid Acrylate‐Oxetane Liquid Crystals
Liquid Crystals
Liquid crystals
Nuclear magnetic resonance of liquid crystals
Nuclear magnetic resonance of liquid crystals
Liquid crystal self-assembly and organic-inorganic hybrid material design
Liquid Crystal Self-Assembly and Organic–Inorganic Hybrid Material Design
Emergent biaxiality in chiral hybrid liquid crystals
Magnetic tuning of liquid crystal dielectric metasurfaces
Hydrogen‐Bonded Siloxane Liquid Crystals for Hybrid Nanomaterials
Dendritic Ligands for Magnetic Suspensions in Liquid Crystals
Wavelength‐Selective Photopolymerization of Hybrid Acrylate‐Oxetane Liquid Crystals
Wavelength‐Selective Photopolymerization of Hybrid Acrylate‐Oxetane Liquid Crystals
Liquid Crystals
Liquid crystals
Nuclear magnetic resonance of liquid crystals
Nuclear magnetic resonance of liquid crystals
Liquid crystal self-assembly and organic-inorganic hybrid material design
Liquid Crystal Self-Assembly and Organic–Inorganic Hybrid Material Design
Emergent biaxiality in chiral hybrid liquid crystals
Magnetic tuning of liquid crystal dielectric metasurfaces
Hydrogen‐Bonded Siloxane Liquid Crystals for Hybrid Nanomaterials
Dendritic Ligands for Magnetic Suspensions in Liquid Crystals
Wavelength‐Selective Photopolymerization of Hybrid Acrylate‐Oxetane Liquid Crystals
Wavelength‐Selective Photopolymerization of Hybrid Acrylate‐Oxetane Liquid Crystals
Liquid Crystals