Formation of a Polar Structure in the Metallic Niobium Sulfide Nb4S3

Critical to being able to control the growth patterns of cell-based sensors is being able to understand how the cytoskeleton of the cell maintains its structure and integrity both under mechanical load and in a load-free environment. Our approach to a better understanding of cell growth is to use a computer simulation that incorporates the primary structures, microtubules, necessary for growth along with their observed behaviors and experimentally determined mechanical properties. Microtubules are the main compressive structural support elements for the axon of a neuron and are created via polymerization of α-β tubulin dimers. Our de novo simulation explores the mechanics of the forces between microtubules and the membrane. We hypothesize that axonal growth is most influenced by the location and direction of the force exerted by the microtubule on the membrane, and furthermore that the interplay of forces between microtubules and the inner surface of the cell membrane dictates the polar structure of axons. The simulation will be used to understand cytoskeletal mechanics for the purpose of engineering cells to be used as sensors.

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Polar Structure Formation in Solid Solution of Strontium-Substituted Fluorapatite–Gelatin Composites: From Structural and Morphogenetic Aspects to Pyroelectric Properties

Chemistry of Materials ◽

10.1021/acs.chemmater.0c02993 ◽

2020 ◽

Vol 32 (19) ◽

pp. 8619-8632

Author(s):

Jennifer Knaus ◽

Martin Sommer ◽

Patrick Duchstein ◽

Roman Gumeniuk ◽

Lev Akselrud ◽

...

Keyword(s):

Solid Solution ◽

Structure Formation ◽

Pyroelectric Properties ◽

Polar Structure

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Directed synthesis of a hybrid improper magnetoelectric multiferroic material

Nature Communications ◽

10.1038/s41467-021-25098-1 ◽

2021 ◽

Vol 12 (1) ◽

Author(s):

Tong Zhu ◽

Fabio Orlandi ◽

Pascal Manuel ◽

Alexandra S. Gibbs ◽

Weiguo Zhang ◽

...

Keyword(s):

Low Temperature ◽

Magnetic Moment ◽

Ferroelectric Material ◽

Polar Phase ◽

Antiferromagnetic State ◽

Exchange Reactions ◽

Polar Structure ◽

Directed Synthesis ◽

Atom Displacement ◽

Spontaneous Magnetic Moment

AbstractPreparing materials which simultaneously exhibit spontaneous magnetic and electrical polarisations is challenging as the electronic features which are typically used to stabilise each of these two polarisations in materials are contradictory. Here we show that by performing low-temperature cation-exchange reactions on a hybrid improper ferroelectric material, Li2SrTa2O7, which adopts a polar structure due to a cooperative tilting of its constituent TaO6 octahedra rather than an electronically driven atom displacement, a paramagnetic polar phase, MnSrTa2O7, can be prepared. On cooling below 43 K the Mn2+ centres in MnSrTa2O7 adopt a canted antiferromagnetic state, with a small spontaneous magnetic moment. On further cooling to 38 K there is a further transition in which the size of the ferromagnetic moment increases coincident with a decrease in magnitude of the polar distortion, consistent with a coupling between the two polarisations.

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High-temperature structural evolution of hexagonal multiferroic YMnO3and YbMnO3

Journal of Applied Crystallography ◽

10.1107/s0021889807025101 ◽

2007 ◽

Vol 40 (4) ◽

pp. 730-734 ◽

Cited By ~ 40

Author(s):

Il-Kyoung Jeong ◽

N. Hur ◽

Th. Proffen

Keyword(s):

Phase Transition ◽

High Temperature ◽

Powder Diffraction ◽

Structural Parameters ◽

Structural Evolution ◽

Neutron Powder Diffraction ◽

Temperature Behaviour ◽

Rietveld Refinements ◽

Polar Structure ◽

Diffraction Patterns

Neutron powder diffraction studies on the structural evolution of hexagonal multiferroic YMnO3and YbMnO3from 1000 K to 1400 K, and from 1000 K to 1350 K, respectively, are presented. The temperature evolution of diffraction patterns suggests that YMnO3undergoes a phase transition to a non-polar structure above 1200 K, while YbMnO3remains ferroelectric up to 1350 K. Detailed structural parameters were obtained as a function of temperature from Rietveld refinements. Based on this result, the distinct differences in temperature behaviour between YMnO3and YbMnO3, and the origin of the ferroelectricity in these hexagonal multiferroics are discussed.

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