Microstructural modelling of hard-magnetic soft materials: Dipole–dipole interactions versus Zeeman effect

AbstractA successful observation and analysis of the Zeeman effect on the near 1.54 μm photoluminescence spectrum in Er-doped crystalline MBE-grown silicon are reported. A clearly resolved splitting of 5 major spectral components was observed in magnetic fields up to 5.5 T. Based on the analysis of the data the symmetry of the dominant optically active center was conclusively established as orthorhombic I (C2v), with g‼≈18.4 and g⊥≈0 in the ground state. The fact that g⊥≈0 explains why EPR detection of Er-related optically active centers in silicon may be difficult. Preferential generation of a single type of an optically active Er-related center in MBE growth confirmed in this study is essential for photonic applications of Si:Er.

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Hierarchical Structures in Soft Materials

NIPPON GOMU KYOKAISHI ◽

10.2324/gomu.91.365 ◽

2018 ◽

Vol 91 (10) ◽

pp. 365-369

Author(s):

Mikihito TAKENAKA

Keyword(s):

Hierarchical Structures ◽

Soft Materials

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Tuning the Magnetic Vortex State in Magnetite Nanodiscs for Remote Control of Biological Signalling

10.26434/chemrxiv.10299506.v1 ◽

2019 ◽

Author(s):

Danijela Gregurec ◽

Alexander W. Senko ◽

Andrey Chuvilin ◽

Pooja Reddy ◽

Ashwin Sankararaman ◽

...

Keyword(s):

Remote Control ◽

Ion Channels ◽

Ground State ◽

Magnetic Particles ◽

Colloidal Stability ◽

Vortex State ◽

Magnetic Vortex ◽

Electron Holography ◽

Dipole Interactions ◽

Magnetite Particles

In this work, we demonstrate the application of anisotropic magnetite nanodiscs (MNDs) as transducers of torque to mechanosensory cells under weak, slowly varying magnetic fields (MFs). These MNDs possess a ground state vortex configuration of magnetic spins which affords greater colloidal stability due to eliminated dipole-dipole interactions characteristic of isotropic magnetic particles of similar size. We first predict vortex magnetization using micromagnetic stimulations in sub-micron anisotropic magnetite particles and then use electron holography to experimentally investigate the magnetization of MNDs 98–226 nm in diameter. When MNDs are coupled to MFs, they transition between vortex and in-plane magnetization allowing for the exertion of the torque on the pN scale, which is sufficient to activate mechanosensitive ion channels in cell membranes.<br>

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Measuring the Magnetic Field Using the Zeeman Effect in Nuclear Quadrupole Resonance of GaSe and InSe Compounds

Journal of Nano- and Electronic Physics ◽

10.21272/jnep.8(4(2)).04081 ◽

2016 ◽

Vol 8 (4(2)) ◽

pp. 04081-1-04081-4 ◽

Cited By ~ 1

Author(s):

A. P. Samila ◽

◽

G. I. Lastivka ◽

V. O. Khandozhko ◽

◽

...

Keyword(s):

Magnetic Field ◽

Nuclear Quadrupole Resonance ◽

Zeeman Effect ◽

Quadrupole Resonance ◽

Nuclear Quadrupole ◽

The Magnetic Field

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Constructing Quantum Mechanics

10.1093/oso/9780198845478.001.0001 ◽

2019 ◽

Author(s):

Anthony Duncan ◽

Michel Janssen

Keyword(s):

Quantum Mechanics ◽

Quantum Theory ◽

Stark Effect ◽

Zeeman Effect ◽

Black Body ◽

Black Body Radiation ◽

Wave Mechanics ◽

Specific Heats ◽

Old Quantum Theory ◽

Upper Level

This is the first of two volumes on the genesis of quantum mechanics. It covers the key developments in the period 1900–1923 that provided the scaffold on which the arch of modern quantum mechanics was built in the period 1923–1927 (covered in the second volume). After tracing the early contributions by Planck, Einstein, and Bohr to the theories of black‐body radiation, specific heats, and spectroscopy, all showing the need for drastic changes to the physics of their day, the book tackles the efforts by Sommerfeld and others to provide a new theory, now known as the old quantum theory. After some striking initial successes (explaining the fine structure of hydrogen, X‐ray spectra, and the Stark effect), the old quantum theory ran into serious difficulties (failing to provide consistent models for helium and the Zeeman effect) and eventually gave way to matrix and wave mechanics. Constructing Quantum Mechanics is based on the best and latest scholarship in the field, to which the authors have made significant contributions themselves. It breaks new ground, especially in its treatment of the work of Sommerfeld and his associates, but also offers new perspectives on classic papers by Planck, Einstein, and Bohr. Throughout the book, the authors provide detailed reconstructions (at the level of an upper‐level undergraduate physics course) of the cental arguments and derivations of the physicists involved. All in all, Constructing Quantum Mechanics promises to take the place of older books as the standard source on the genesis of quantum mechanics.

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Depth-Sensing Indentation as a Micro- and Nanomechanical Approach to Characterisation of Mechanical Properties of Soft, Biological, and Biomimetic Materials

Nanomaterials ◽

10.3390/nano10010015 ◽

2019 ◽

Vol 10 (1) ◽

pp. 15 ◽

Cited By ~ 1

Author(s):

Nikolay V. Perepelkin ◽

Feodor M. Borodich ◽

Alexander E. Kovalev ◽

Stanislav N. Gorb

Keyword(s):

Review Paper ◽

Soft Materials ◽

Data Fitting ◽

Depth Sensing ◽

Adhesive Properties ◽

Distinctive Features ◽

Experimental Part ◽

Properties Of Materials ◽

The Mathematical Model ◽

Non Destructive

Classical methods of material testing become extremely complicated or impossible at micro-/nanoscale. At the same time, depth-sensing indentation (DSI) can be applied without much change at various length scales. However, interpretation of the DSI data needs to be done carefully, as length-scale dependent effects, such as adhesion, should be taken into account. This review paper is focused on different DSI approaches and factors that can lead to erroneous results, if conventional DSI methods are used for micro-/nanomechanical testing, or testing soft materials. We also review our recent advances in the development of a method that intrinsically takes adhesion effects in DSI into account: the Borodich–Galanov (BG) method, and its extended variant (eBG). The BG/eBG methods can be considered a framework made of the experimental part (DSI by means of spherical indenters), and the data processing part (data fitting based on the mathematical model of the experiment), with such distinctive features as intrinsic model-based account of adhesion, the ability to simultaneously estimate elastic and adhesive properties of materials, and non-destructive nature.

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