Category:2D materials: Difference between revisions
(Created page with "= Category:Surfaces = The '''Surfaces''' category contains pages related to modelling, analysis, and theory of surfaces using VASP. Topics include how to treat slab geometries, surface‐specific corrections, and surface properties such as work functions or adsorption. == Related pages == * Computing the work function * Electrostatic corrections * IDIPOL * CO on Ni 111 surface") |
No edit summary |
||
| Line 1: | Line 1: | ||
Every real crystal or material has a surface. In VASP simulations, however, periodic boundary conditions typically model an infinite crystal, the perfect bulk. | |||
To model a surface, a thin film, or an intrinsically 2D material in VASP, therefore, requires breaking these periodic boundary conditions intentionally. This is done by elongating the simulation cell in one direction (normal to the intended surface) without adding more atoms. This creates a vacuum region between repeated images of thin films of material (commonly called surface slabs, or just slabs), each of which has two surfaces. | |||
{{NB|mind|It is not possible to create only a single surface in an atomistic model. Cleaving a bulk material inevitably produces two surfaces. These two surfaces are generally nonequivalent, although they may be identical depending on the material and the cleavage plane.}} | |||
===Nomenclature=== | |||
====Surfaces==== | |||
As discussed above, in atomistic simulations employing periodic boundary conditions, surfaces are modeled as thin films of a material separated by a vacuum region of sufficient thickness. When the surface itself is the primary focus, the slab model must be constructed to mimic a semi-infinite bulk crystal beneath the surface. The second surface, located on the opposite side of the slab, should be sufficiently separated to prevent strong interactions between the two surfaces. | |||
====Thin films==== | |||
Although thin-film simulations often employ the same computational setup and slab model as surface calculations, their objective differs. In thin-film studies, the goal is to investigate the behavior and properties of the entire system — including both surfaces and the bulk-like interior region — rather than isolating the characteristics of a single surface. | |||
====2D materials==== | |||
This class of materials comprises ultrathin films consisting of only a few atomic layers. Prototypical examples include graphene, which is one atomic layer thick, and molybdenum disulfide (MoS$_2$), which consists of three atomic layers. Such materials can occur naturally as van der Waals–bonded layered crystals, but they can also be exfoliated and studied as mono-, bi-, or few-layer systems. | |||
== Related pages == | == Related pages == | ||
Revision as of 15:29, 16 October 2025
Every real crystal or material has a surface. In VASP simulations, however, periodic boundary conditions typically model an infinite crystal, the perfect bulk. To model a surface, a thin film, or an intrinsically 2D material in VASP, therefore, requires breaking these periodic boundary conditions intentionally. This is done by elongating the simulation cell in one direction (normal to the intended surface) without adding more atoms. This creates a vacuum region between repeated images of thin films of material (commonly called surface slabs, or just slabs), each of which has two surfaces.
| Mind: It is not possible to create only a single surface in an atomistic model. Cleaving a bulk material inevitably produces two surfaces. These two surfaces are generally nonequivalent, although they may be identical depending on the material and the cleavage plane. |
Nomenclature
Surfaces
As discussed above, in atomistic simulations employing periodic boundary conditions, surfaces are modeled as thin films of a material separated by a vacuum region of sufficient thickness. When the surface itself is the primary focus, the slab model must be constructed to mimic a semi-infinite bulk crystal beneath the surface. The second surface, located on the opposite side of the slab, should be sufficiently separated to prevent strong interactions between the two surfaces.
Thin films
Although thin-film simulations often employ the same computational setup and slab model as surface calculations, their objective differs. In thin-film studies, the goal is to investigate the behavior and properties of the entire system — including both surfaces and the bulk-like interior region — rather than isolating the characteristics of a single surface.
2D materials
This class of materials comprises ultrathin films consisting of only a few atomic layers. Prototypical examples include graphene, which is one atomic layer thick, and molybdenum disulfide (MoS$_2$), which consists of three atomic layers. Such materials can occur naturally as van der Waals–bonded layered crystals, but they can also be exfoliated and studied as mono-, bi-, or few-layer systems.
Related pages
Pages in category "2D materials"
This category contains only the following page.