Graphite TS binding energy: Difference between revisions
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== Download == | == Download == | ||
[http://www.vasp.at/vasp-workshop/examples/graphiteBinding_ts.tgz graphiteBinding_ts.tgz] | [http://www.vasp.at/vasp-workshop/examples/graphiteBinding_ts.tgz graphiteBinding_ts.tgz] | ||
== References == | |||
<references> | |||
<ref name="Tkatchenko09">[http://onlinelibrary.wiley.com/doi/10.1002/jcc.20495/abstract A. Tkatchenko and M. Scheffler, Phys. Rev. Lett. 102, 073005 (2009).]</ref> | |||
<ref name="bucko">[http://journals.aps.org/prb/abstract/10.1103/PhysRevB.87.064110 T. Bučko, S. Lebègue, J. Hafner, and J. G. Ángyán, Phys. Rev. B 87, 064110 (2013).]</ref> | |||
<ref name="kerber">[http://onlinelibrary.wiley.com/doi/10.1002/jcc.21069/abstract Kerber and J. Sauer, J. Comp. Chem. 29, 2088 (2008).]</ref> | |||
</references> | |||
---- | ---- | ||
[[VASP_example_calculations|To the list of examples]] or to the [[The_VASP_Manual|main page]] | [[VASP_example_calculations|To the list of examples]] or to the [[The_VASP_Manual|main page]] | ||
[[Category:Examples]] | [[Category:Examples]] |
Revision as of 12:35, 10 May 2017
Task
Determine the interlayer binding energy of graphite in its experimental structure using the method of Tchatchenko and Scheffler to account for van der Waals interactions.
Input
POSCAR
- Graphite:
graphite 1.0 1.22800000 -2.12695839 0.00000000 1.22800000 2.12695839 0.00000000 0.00000000 0.00000000 6.71 4 direct 0.00000000 0.00000000 0.25000000 0.00000000 0.00000000 0.75000000 0.33333333 0.66666667 0.25000000 0.66666667 0.33333333 0.75000000
- Graphene:
graphite 1.0 1.22800000 -2.12695839 0.00000000 1.22800000 2.12695839 0.00000000 0.00000000 0.00000000 20. 2 direct 0.00000000 0.00000000 0.25000000 0.33333333 0.66666667 0.25000000
INCAR
IVDW=20 LVDW_EWALD =.TRUE. NSW=1 IBRION=2 ISIF=4 PREC=Accurate EDIFFG=1e-5 LWAVE=.FALSE. LCHARG=.FALSE. ISMEAR=-5 SIGMA = 0.01 EDIFF=1e-6 ALGO=Fast NPAR=2
KPOINTS
- Graphite:
Monkhorst Pack 0 gamma 16 16 8 0 0 0
- Graphene:
Monkhorst Pack 0 gamma 16 16 1 0 0 0
There is no interaction of layers in z-direction for graphene so we need only 1 k point in this direction.
Calculation
Semilocal DFT at the GGA level underestimates long-range dispersion interactions. In the case of graphite, PBE predicts the interlayer binding energy of ~1 meV/atom which is too small compared to the RPA reference of 0.048 eV/atom (Lebgue et al., PRL 105, 195401 (2010)).
In this example, the interlayer binding energy of graphite in its experimental structure is determined using the TS method of Tchatchenko and Scheffler (PRL 102, 073005 (2009)), which performs well in description of the structure of graphite (see e.g. example graphiteDistance_ts).
The calculation is performed in two steps (sigle-point calculations) in which the energy for bulk graphite and for graphene are obtained. The binding energy is computed automatically and it is written in the file results.dat.
Even though the TS method predicts a reasonable geometry it overestimates the energetics strongly: the computed binding energy of -0.083 eV/atom is too large compared to the RPA reference of 0.048 eV/atom This overestimation is - at least in part - due to neglecting the many-body interactions (see example graphiteBinding_mbd).
Details of implementation of TS in VASP + a number of tests: Bucko et al., PRB 87, 064110 (2013).
Used INCAR Tags
ALGO, EDIFF, EDIFFG, IBRION, ISIF, ISMEAR, IVDW, LCHARG, LVDW_EWALD, LWAVE, NPAR, NSW, PREC, SIGMA
Download
References
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To the list of examples or to the main page