We predict a thermodynamic magnon recoil effect for domain wall motions in the presence of temperature gradients. All current thermodynamic theories assert that a magnetic domain wall must move toward the hotter side, based on equilibrium thermodynamic arguments. Microscopic calculations, on the other hand, show that a domain wall can move either along or against the direction of heat currents, depending on how strong the magnonic heat currents are reflected by the domain wall. We have resolved the inconsistency between these two approaches by augmenting the theory in the presence of thermal gradients by incorporating in the free energy of domain walls a heat current term present in nonequilibrium steady states. The condition to observe a d...
We present a theoretical study of magnon-mediated heat transport in electrically insulating ferromag...
Nowadays, domain walls and generally magnetic domains play a vital role in the development of techno...
The problem, of dissipative motion of domain walls (DW) in the case of tetramethyl ammonium manganes...
We predict a thermodynamic magnon recoil effect for domain wall motions in the presence of temperatu...
Control of magnetic domain wall motion holds promise for efficient manipulation and transfer of magn...
Thermally driven domain wall (DW) motion caused solely by magnonic spin currents was forecast theore...
The issue of whether a thermal gradient acts like a magnetic field or an electric current in the dom...
[EN] Magnetic domain wall (DW) motion induced by a localized Gaussian temperature profile is studied...
The recently discovered spin Seebeck effect refers to a spin current induced by a temperature gradie...
We present a model for the dynamics of current-driven and field-driven domain-wall lines at nonzero ...
Magnetic domain walls are proposed as data carriers in future spintronic devices, whose reliability ...
We predict that magnon motive force can lead to temperature dependent, nonlinear chiral damping in b...
So far, we have derived some general expressions for domain-wall motion and the spin motive force. W...
Momentum transfer from incoming magnons to a Bloch domain wall is calculated using one-dimensional c...
We employ the Landau-Lifshitz-Bloch (LLB) equation to investigate current-induced domain wall motion...
We present a theoretical study of magnon-mediated heat transport in electrically insulating ferromag...
Nowadays, domain walls and generally magnetic domains play a vital role in the development of techno...
The problem, of dissipative motion of domain walls (DW) in the case of tetramethyl ammonium manganes...
We predict a thermodynamic magnon recoil effect for domain wall motions in the presence of temperatu...
Control of magnetic domain wall motion holds promise for efficient manipulation and transfer of magn...
Thermally driven domain wall (DW) motion caused solely by magnonic spin currents was forecast theore...
The issue of whether a thermal gradient acts like a magnetic field or an electric current in the dom...
[EN] Magnetic domain wall (DW) motion induced by a localized Gaussian temperature profile is studied...
The recently discovered spin Seebeck effect refers to a spin current induced by a temperature gradie...
We present a model for the dynamics of current-driven and field-driven domain-wall lines at nonzero ...
Magnetic domain walls are proposed as data carriers in future spintronic devices, whose reliability ...
We predict that magnon motive force can lead to temperature dependent, nonlinear chiral damping in b...
So far, we have derived some general expressions for domain-wall motion and the spin motive force. W...
Momentum transfer from incoming magnons to a Bloch domain wall is calculated using one-dimensional c...
We employ the Landau-Lifshitz-Bloch (LLB) equation to investigate current-induced domain wall motion...
We present a theoretical study of magnon-mediated heat transport in electrically insulating ferromag...
Nowadays, domain walls and generally magnetic domains play a vital role in the development of techno...
The problem, of dissipative motion of domain walls (DW) in the case of tetramethyl ammonium manganes...
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