Examples of 'antiferromagnetic' in a sentence
Meaning of "antiferromagnetic"
Antiferromagnetic is an adjective used to describe a material that exhibits antiferromagnetism, a phenomenon where magnetic moments align in an alternating pattern
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- Exhibiting antiferromagnetism.
How to use "antiferromagnetic" in a sentence
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antiferromagnetic
This observation is consistent with an antiferromagnetic scenario.
The antiferromagnetic layer then becomes antiferromagnetic again.
Demonstration of a physical mechanism allowing achievement of antiferromagnetic memories.
Antiferromagnetic materials become paramagnetic above a certain temperature.
At cryogenic temperatures some austenites are antiferromagnetic.
It is also antiferromagnetic at low temperatures.
The direction of its magnetisation is fixed by an antiferromagnetic exchange layer.
There is antiferromagnetic order because the singlet state is energetically favoured.
The zero point spin reduction for antiferromagnetic MnO is calculated.
The antiferromagnetic layer is not separately visible in this top view.
It is a black antiferromagnetic solid.
Means of controlling the temperature of the second layer of antiferromagnetic material.
A very simple antiferromagnetic structure.
Controller configured to control the temperature of the layer of antiferromagnetic material.
An ordered antiferromagnetic material exhibits exchange coupling after deposition on a ferromagnetic material.
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It consists of a ferromagnetic and an antiferromagnetic thin film in contact to each other.
It can only be determined that the average correlation of neighbour spins is antiferromagnetic.
The dimeric complex shows significant antiferromagnetic exchange between cobalt centres.
The stack preferably comprises a plurality of ferromagnetic layers and a plurality of antiferromagnetic layers.
These experiments show strong antiferromagnetic fluctuations in both normal and superconducting states.
These data were fitted according to yosida and nagamiya theory of antiferromagnetic resonance.
The reference layer may be a synthetic antiferromagnetic to fix the direction of its magnetization.
The fluctuations in the correlated metal compound show a predominance of antiferromagnetic correlations.
Heating of the second antiferromagnetic layer by other external heating means could also be envisaged.
They give rise to localized magnetic moments that acquire an antiferromagnetic order.
This antiferromagnetic coupling therefore opposes the rotation of magnetizations when an external field is applied.
These properties are explained in function of a magnetoelectricity mediated antiferromagnetic domain wall ordering model.
This synthetic antiferromagnetic layer can itself be trapped by interaction with another antiferromagnetic layer.
Magnetic ordering differs in superlattices with ferromagnetic and antiferromagnetic interaction between the layers.
Terahertz antiferromagnetic excitations driven by spin-current.
Theoretical calculations on these phases have shown that this coupling is of the antiferromagnetic type.
The calculations considered both the ferromagnetic and antiferromagnetic configurations for each nickel concentration.
Such systems exhibit a lower saturation field and a larger δH than superlattices with antiferromagnetic coupling.
The study of binuclear systems exhibiting intramolecular antiferromagnetic coupling has led to original photomagnetic behaviours.
A major bottleneck for functional devices is the readout and electric control of the antiferromagnetic order.
The invention concerns a method for fabrication of an antiferromagnetic and temperature compensated timepiece balance spring.
The magnetic studies reveal anisotropy in the susceptibilities and the presence of significant antiferromagnetic exchange.
The magnetic susceptibility of an antiferromagnetic material typically shows a maximum at the Néel temperature.
Magnetic susceptibility studies on the dimeric and trimetallic complex show them to exhibit antiferromagnetic behaviour.
The main advantages of antiferromagnetic material are,.
Below the Néel temperature the susceptibility decreases and the substance becomes antiferromagnetic.
In this compound, an antiferromagnetic glass competes with superconductivity.
Here the ferromagnetic layer is a CoFeB alloy and the antiferromagnetic layer is a PtMn alloy.
In practice, this antiferromagnetic layer is based on IrMn or FeMn.
The hysteresis loop confirms the metamagnetic transition from paramagnetic to antiferromagnetic at low magnetic field.
In the antiferromagnetic case, a divergence is observed in the staggered susceptibility.
GMR can also be observed in the absence of antiferromagnetic coupling layers.
This antiferromagnetic layer is for example NiO, FeMn or PtMn.
They probably highlight the coupling of intermolecular phonons with antiferromagnetic fluctuations around Tcoh.
Antiferromagnetic exchange is present in compound 2.
