Quantum chemical molecular dynamics simulations of graphene nucleation on the Ni(111) surface show that graphene creates its own step-edge as it forms. This "step-edge self-assembly" is driven by the formation of thermodynamically favorable Ni-C sigma-bonds at the graphene edge. This dynamic aspect of the Ni(111) catalyst is in contrast to the commonly accepted view that graphene nucleates on a pre-existing, static catalyst step-edge. Simulations also show that, simply by manipulating the subsurface carbon density, preferential formation of single-layer graphene instead of multi-layer graphene can be achieved on nickel catalysts
Grasping the fundamentals of graphene growth is vital for graphene synthesis. By employing classical...
Chemical vapor deposition (CVD) growth of graphene on Cu(111) has been modeled with quantum chemical...
8siAn operando investigation of graphene growth on (100) grains of polycrystalline nickel (Ni) surfa...
Quantum chemical molecular dynamics simulations of graphene nucleation on the Ni(111) surface show t...
The mechanism of bilayer graphene nucleation and growth has been investigated by using quantum chemi...
The mechanism of bilayer graphene nucleation and growth has been investigated by using quantum chemi...
We present quantum chemical simulations demonstrating graphene precursor formation on bcc (111) tran...
The nucleation of graphene on a transition metal surface, either on a terrace or near a step edge, i...
To explore the mechanism of graphene chemical vapor deposition (CVD) growth on a catalyst surface, a...
The nucleation of graphene on a transition metal surface, either on a terrace or near a step edge, i...
We present quantum chemical simulations demonstrating graphene precursor formation on bcc (111) tran...
We present quantum chemical simulations demonstrating graphene precursor formation on bcc (111) tran...
We present quantum chemical simulations demonstrating graphene precursor formation on bcc (111) tran...
The mechanism and kinetics of graphene formation from amorphous nickel carbides have been investigat...
Graphene nucleation from crystalline Ni₃C has been investigated using quantum chemical molecular dyn...
Grasping the fundamentals of graphene growth is vital for graphene synthesis. By employing classical...
Chemical vapor deposition (CVD) growth of graphene on Cu(111) has been modeled with quantum chemical...
8siAn operando investigation of graphene growth on (100) grains of polycrystalline nickel (Ni) surfa...
Quantum chemical molecular dynamics simulations of graphene nucleation on the Ni(111) surface show t...
The mechanism of bilayer graphene nucleation and growth has been investigated by using quantum chemi...
The mechanism of bilayer graphene nucleation and growth has been investigated by using quantum chemi...
We present quantum chemical simulations demonstrating graphene precursor formation on bcc (111) tran...
The nucleation of graphene on a transition metal surface, either on a terrace or near a step edge, i...
To explore the mechanism of graphene chemical vapor deposition (CVD) growth on a catalyst surface, a...
The nucleation of graphene on a transition metal surface, either on a terrace or near a step edge, i...
We present quantum chemical simulations demonstrating graphene precursor formation on bcc (111) tran...
We present quantum chemical simulations demonstrating graphene precursor formation on bcc (111) tran...
We present quantum chemical simulations demonstrating graphene precursor formation on bcc (111) tran...
The mechanism and kinetics of graphene formation from amorphous nickel carbides have been investigat...
Graphene nucleation from crystalline Ni₃C has been investigated using quantum chemical molecular dyn...
Grasping the fundamentals of graphene growth is vital for graphene synthesis. By employing classical...
Chemical vapor deposition (CVD) growth of graphene on Cu(111) has been modeled with quantum chemical...
8siAn operando investigation of graphene growth on (100) grains of polycrystalline nickel (Ni) surfa...