Novel Ferroic Materials with Functionally active Domain Walls

Lead Research Organisation: University of St Andrews
Department Name: Chemistry

Abstract

Some functional materials, such as ferroelectrics, contain membrane or sheet structures called "domain walls". For decades, domain walls were dismissed as being minor microstructural components of little significance. It is now clear that nothing could be further from the truth. Domain walls often, in fact, have unique functional properties that are completely different from the domains that they surround: they can be conductors or superconductors when the rest of the material is insulating; they can display magnetic order in non-magnetic crystals and they can possess aligned electrical dipoles when the matrix surrounding them is non-polar. In effect, domain walls represent a new class of sheet-like nanoscale functional material.

The aim is to 1) synthesis and characterise novel ferroic materials with potentially exciting domain structures; and 2) to tune domain wall properties in new and existing materials be appropriate chemical modification (doping). The project will involve: (solid state) synthetic work, including ceramic processing; crystallographic structure determination using both x-ray and neutron diffraction; and electrical characterization using a range of techniques such as dielectric and impedance spectroscopy, polarization-field and thermally stimulated depolarization current measurements.

Publications

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Studentship Projects

Project Reference Relationship Related To Start End Student Name
EP/N509759/1 01/10/2016 30/09/2021
1947532 Studentship EP/N509759/1 01/09/2017 26/08/2021 Grant Howieson
 
Description The material LaTaO4 is isostructural with other crystalline materials which have been proven to be ferroelectric but previous studies have failed to produce similar results in LaTaO4. Closer inspection of the electrical properties eluded to the existence of a different structure at room temperature than wheat is found in similar materials. The new found structure is confirmed to be 'incommensurately modulated', where the crystal structure has no long range periodicity. It has aslo been found that the stability of the aperiodic structure can be controlled by doping the material with different atoms. However, testing samples where the periodicity is restored still did not show a ferroelectric response, suggesting other structural properties play a role in preventing ferroelectric switching - such as the energy required for switching polarisation being too high.

Work to improve conductivity in the region between ferroelectric domains in hexagonal tungsten bronze materials is also ongoing. The materials have so far been successfully doped with electrons but no evident improvement to domain wall conductivity has been seen.
Exploitation Route LaTaO4 can now be added to a list of similar layered oxide perovskite structures which have aperiodic structures and more sensitive characterisation could be conducted to determine how the aperiodic structure modulates more accurately and explore the possible mechanisms which cause it. The discovery that the periodic structure still does not switch ferroelectrically rules out LaTaO4 for device applications.

Work on hexagonal tungsten bronze materials with improved domain wall conduction is ongoing, but if successful could be explored as useful materials in nanoelectronics.
Sectors Chemicals,Electronics,Energy,Manufacturing, including Industrial Biotechology
 
Description Ferroelectric Workshop / Conference 
Form Of Engagement Activity Participation in an activity, workshop or similar
Part Of Official Scheme? No
Geographic Reach International
Primary Audience Other audiences
Results and Impact Knowledge exchange and opportunity to arrange collaborations, involving international experts in the field.
Year(s) Of Engagement Activity 2018,2019,2020