Do FCC Structures only have a CN of 12?

AI Thread Summary
FCC structures typically have a coordination number of 12, but there is tolerance for lattice vacancies and slight atomic site displacements without breaking symmetry. The discussion highlights that real crystals are never perfect and always contain defects, which are usually negligible compared to the total number of atoms. It is suggested that a disordered FCC structure can maintain its symmetry with a limited number of vacancies, with references indicating that up to one vacancy per 1000 atoms may occur at equilibrium in metals. The impact of temperature and purity on defect density is acknowledged, with typical defect densities ranging from one defect per 10,000 to 100,000 atoms. Overall, while FCC structures can tolerate some defects, excessive vacancies may compromise their stability and symmetry.
letshin
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Hi all,

Without first delving too deeply into the literature I wanted to ask if its is only permissible for FCC structures to have a coordination number of 12. In the case of lattice vacancies and/or distortion: wherein the atomic sites are slightly displaced; is there a kind of tolerence for this to happen without breaking the FCC symmetry?

Are there any publications on this topic?

Many thanks,
Let
 
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No real crystal is exactly perfect everywhere - you always have some defects. The number of defects is very small compared to the total number of atoms, so usually they can be neglected if you consider the crystal structure.
 
Cheers. When you say small, what is the order of difference?

In the case of a, say, disordered FCC structure how many vacancies would be needed before the structure loses symmetry and say, no longer shows FCC-type diffraction peaks?
 
letshin said:
Cheers. When you say small, what is the order of difference?
That really depends on the crystal, its temperature, purity and so on.

letshin said:
In the case of a, say, disordered FCC structure how many vacancies would be needed before the structure loses symmetry and say, no longer shows FCC-type diffraction peaks?
I'm not sure if such a broken crystal would still be stable enough to use it as a crystal at all.
Reference 2 of the wikipedia article suggests up to one vacancy per 1000 atoms in equilibrium at the melting point of metals. And that is a very high number of vacancies.
 
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mfb said:
That really depends on the crystal, its temperature, purity and so on.

I'm not sure if such a broken crystal would still be stable enough to use it as a crystal at all.
Reference 2 of the wikipedia article suggests up to one vacancy per 1000 atoms in equilibrium at the melting point of metals. And that is a very high number of vacancies.

Thanks for that. That helped quite a bit - of course I should have checked wiki first at the very least. Silly me.
 

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