My question is about applying an external electric field (with EFIELD=x) on a slab or dot system. Does the energy reported by vasp (TOTEN, or the F=XXX in OSZICAR) have a physical meaning, or does the sloping potential (non-constant vacuum level) mean that the energy is ill-defined?
For example, if I take a system with EFIELD=0, EFIELD=1, and EFIELD=-1, does the difference in total energy of the 3 calculations reflect the amount of work done by the electric field on the system, or is the number ill-defined?
Thanks very much,
Tim Holme
electric field and the total system energy
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tholme
electric field and the total system energy
Last edited by tholme on Mon May 17, 2010 7:58 pm, edited 1 time in total.
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tholme
electric field and the total system energy
For those interested, the response from admin was:
Good question.
Actually the implementation was initially done by Peter Feibelman,
and there is a paper out explaining the details. [DOI: 10.1103/PhysRevB.64.125403
Surface-diffusion mechanism versus electric field: Pt/Pt(001)
Peter J. Feibelman, PHYSICAL REVIEW B, VOLUME 64, 125403]
However, at one point I rewrote the code, and if I recall correctly, I tested that the energy changes are correct. e.g. the first derivative of the energy w.r.t. a field should be the dipol. The second derivative should be the polarizability.
And these tests went well.
Good question.
Actually the implementation was initially done by Peter Feibelman,
and there is a paper out explaining the details. [DOI: 10.1103/PhysRevB.64.125403
Surface-diffusion mechanism versus electric field: Pt/Pt(001)
Peter J. Feibelman, PHYSICAL REVIEW B, VOLUME 64, 125403]
However, at one point I rewrote the code, and if I recall correctly, I tested that the energy changes are correct. e.g. the first derivative of the energy w.r.t. a field should be the dipol. The second derivative should be the polarizability.
And these tests went well.
Last edited by tholme on Tue Jun 08, 2010 1:31 am, edited 1 time in total.