Add to ORKGWe introduce a microscopic model to describe the ultrafast response of magnetic materials with two sublattices to heating by a femtosecond laser pulse. Even though the model is based on a set of simple Hamiltonians, it readily reproduces experimental observations such as ultrafast reversal of ferrimagnets and delayed demagnetization of one sublattice in ferromagnetic alloys. The calculations give insight into the microscopic mechanisms and thermodynamics governing the complex dynamics of these multisublattice magnets
The question of how, and how fast, magnetization can be reversed is a topic of great practical inter...
The question of how, and how fast, magnetization can be reversed is a topic of great practical inter...
The question of how, and how fast, magnetization can be reversed is a topic of great practical inter...
We introduce a microscopic model to describe the ultrafast response of magnetic materials with two s...
We introduce a microscopic model to describe the ultrafast response of magnetic materials with two s...
We introduce a microscopic model to describe the ultrafast response of magnetic materials with two s...
We introduce a microscopic model to describe the ultrafast response of magnetic materials with two s...
We present a microscopic model that explains quenching of the magnetization of ferromagnetic transit...
We present a microscopic model that explains quenching of the magnetization of ferromagnetic transit...
We present a microscopic model that explains quenching of the magnetization of ferromagnetic transit...
We present a microscopic model that explains quenching of the magnetization of ferromagnetic transit...
We present a microscopic model that explains quenching of the magnetization of ferromagnetic transit...
We present a microscopic model that explains quenching of the magnetization of ferromagnetic transit...
Atomistic and mesoscopic-scale spin dynamics have proven to be a powerful tool for studying magnetiz...
The study of magnetism has long been an active area of interest for the scientific research, while a...
The question of how, and how fast, magnetization can be reversed is a topic of great practical inter...
The question of how, and how fast, magnetization can be reversed is a topic of great practical inter...
The question of how, and how fast, magnetization can be reversed is a topic of great practical inter...
We introduce a microscopic model to describe the ultrafast response of magnetic materials with two s...
We introduce a microscopic model to describe the ultrafast response of magnetic materials with two s...
We introduce a microscopic model to describe the ultrafast response of magnetic materials with two s...
We introduce a microscopic model to describe the ultrafast response of magnetic materials with two s...
We present a microscopic model that explains quenching of the magnetization of ferromagnetic transit...
We present a microscopic model that explains quenching of the magnetization of ferromagnetic transit...
We present a microscopic model that explains quenching of the magnetization of ferromagnetic transit...
We present a microscopic model that explains quenching of the magnetization of ferromagnetic transit...
We present a microscopic model that explains quenching of the magnetization of ferromagnetic transit...
We present a microscopic model that explains quenching of the magnetization of ferromagnetic transit...
Atomistic and mesoscopic-scale spin dynamics have proven to be a powerful tool for studying magnetiz...
The study of magnetism has long been an active area of interest for the scientific research, while a...
The question of how, and how fast, magnetization can be reversed is a topic of great practical inter...
The question of how, and how fast, magnetization can be reversed is a topic of great practical inter...
The question of how, and how fast, magnetization can be reversed is a topic of great practical inter...