Atomistic spin model simulations are immensely useful in determining temperature dependent magnetic prop- erties, but are known to give the incorrect dependence of the magnetization on temperature compared to exper- iment owing to their classical origin. We find a single parameter rescaling of thermal fluctuations which gives quantitative agreement of the temperature dependent magnetization between atomistic simulations and experi- ment for the elemental ferromagnets Ni, Fe, Co and Gd. Simulating the sub-picosecond magnetization dynam- ics of Ni under the action of a laser pulse we also find quantitative agreement with experiment in the ultrafast regime. This enables the quantitative determination of temperature dependent magnetic propertie...
A hierarchical multiscale approach to model the magnetization dynamics of ferromagnetic random alloy...
The purpose of this research is to have a quantitative analysis on the temperature dependence magnet...
We introduce a microscopic model to describe the ultrafast response of magnetic materials with two s...
Atomistic spin model simulations are immensely useful in determining temperature dependent magnetic ...
Multireservoir models are widely used for modeling and interpreting ultrafast magnetization dynamics...
Atomistic modelling of magnetic materials provides unprecedented detail about the underlying physica...
For finite-temperature micromagnetic simulations the knowledge of the temperature dependence of the ...
Author name used in this publication: C. H. Woo2008-2009 > Academic research: refereed > Publication...
This work presents new theoretical developments of atomistic spin simulations of magnetic materials ...
The microscopic mechanisms responsible for the ultrafast loss of magnetic order triggered in ferroma...
The use of the classical Heisenberg model which incorporates only transverse spin degrees of freedom...
Ultrafast laser excitation of ferromagnetic metals gives rise to correlated, highly non-equilibrium ...
The microscopic mechanisms responsible for the ultrafast loss of magnetic order triggered in ferroma...
A scheme is presented that is based on the alloy analogy model and allows one to account for thermal...
Spin-disorder resistivity of Fe and Ni and its temperature dependence are analyzed using noncollinea...
A hierarchical multiscale approach to model the magnetization dynamics of ferromagnetic random alloy...
The purpose of this research is to have a quantitative analysis on the temperature dependence magnet...
We introduce a microscopic model to describe the ultrafast response of magnetic materials with two s...
Atomistic spin model simulations are immensely useful in determining temperature dependent magnetic ...
Multireservoir models are widely used for modeling and interpreting ultrafast magnetization dynamics...
Atomistic modelling of magnetic materials provides unprecedented detail about the underlying physica...
For finite-temperature micromagnetic simulations the knowledge of the temperature dependence of the ...
Author name used in this publication: C. H. Woo2008-2009 > Academic research: refereed > Publication...
This work presents new theoretical developments of atomistic spin simulations of magnetic materials ...
The microscopic mechanisms responsible for the ultrafast loss of magnetic order triggered in ferroma...
The use of the classical Heisenberg model which incorporates only transverse spin degrees of freedom...
Ultrafast laser excitation of ferromagnetic metals gives rise to correlated, highly non-equilibrium ...
The microscopic mechanisms responsible for the ultrafast loss of magnetic order triggered in ferroma...
A scheme is presented that is based on the alloy analogy model and allows one to account for thermal...
Spin-disorder resistivity of Fe and Ni and its temperature dependence are analyzed using noncollinea...
A hierarchical multiscale approach to model the magnetization dynamics of ferromagnetic random alloy...
The purpose of this research is to have a quantitative analysis on the temperature dependence magnet...
We introduce a microscopic model to describe the ultrafast response of magnetic materials with two s...