Add to ORKGAbstract. Graphene, a plane object composed of carbon atoms, is a perspective material for nanoelectronics and spintronics because of its unique electron and magnetic properties. It was found that graphene reveals spin polarization effect, i.e. its magnetic features increase when crystal defects (vacancies and clusters of vacancies) are introduced. Systematic analysis is per-formed by ab initio simulation with the use of VASP program complex in order to state spin polarization dependence of graphene on the number vacancies in a cluster and on a cluster con-figuration
The possibility to induce a magnetic response in graphene by the introduction of defects has been ge...
The observation of intrinsic magnetic order in graphene and graphene-based materials relies on the f...
Doping of the graphene lattice with transition-metal atoms resulting in a high magnetic anisotropy e...
Spin-polarized density functional theory has been used to study the effects of vacancy defects on th...
Spin-polarized density functional theory has been used to study the effects of vacancy defects on th...
Vacancy-induced magnetization of a graphene layer is investigated by means of a first-principles DFT...
The experimental realization of two-dimensional materials such as graphene, silicene and germanene h...
doi:10.1088/1367-2630/6/1/068 Abstract. Spin-polarized density functional theory has been used to st...
We address the electronic structure and magnetic properties of vacancies and voids both in graphene ...
After general discussion of itinerant-electron magetism, Hubbard model and Lieb theorem, we discuss ...
Control of magnetism by applied voltage is desirable for spintronics applications. Finding a suitabl...
[[abstract]]One intriguing finding in graphene is the vacancy-induced magnetism that highlights the ...
Graphene clusters consisting of 24 to 150 carbon atoms and hydrogen termination at the zigzag bounda...
The science for processing and control of electron spins is referred to as “Spintronics”. Metals, se...
Patterned vacancy clusters (or nanoholes) can modify the electronic structure of graphene, and there...
The possibility to induce a magnetic response in graphene by the introduction of defects has been ge...
The observation of intrinsic magnetic order in graphene and graphene-based materials relies on the f...
Doping of the graphene lattice with transition-metal atoms resulting in a high magnetic anisotropy e...
Spin-polarized density functional theory has been used to study the effects of vacancy defects on th...
Spin-polarized density functional theory has been used to study the effects of vacancy defects on th...
Vacancy-induced magnetization of a graphene layer is investigated by means of a first-principles DFT...
The experimental realization of two-dimensional materials such as graphene, silicene and germanene h...
doi:10.1088/1367-2630/6/1/068 Abstract. Spin-polarized density functional theory has been used to st...
We address the electronic structure and magnetic properties of vacancies and voids both in graphene ...
After general discussion of itinerant-electron magetism, Hubbard model and Lieb theorem, we discuss ...
Control of magnetism by applied voltage is desirable for spintronics applications. Finding a suitabl...
[[abstract]]One intriguing finding in graphene is the vacancy-induced magnetism that highlights the ...
Graphene clusters consisting of 24 to 150 carbon atoms and hydrogen termination at the zigzag bounda...
The science for processing and control of electron spins is referred to as “Spintronics”. Metals, se...
Patterned vacancy clusters (or nanoholes) can modify the electronic structure of graphene, and there...
The possibility to induce a magnetic response in graphene by the introduction of defects has been ge...
The observation of intrinsic magnetic order in graphene and graphene-based materials relies on the f...
Doping of the graphene lattice with transition-metal atoms resulting in a high magnetic anisotropy e...