Ordered lattice necessary for band structure?

Hyo X
Messages
101
Reaction score
11
Is it possible for a disordered or amorphous structure to have band structure?

I understand derivation of bands from Kronig-Penney model.

E.g. does amorphous silicon have a band structure?
While amorphous silicon oxide does not have a band structure?
 
Physics news on Phys.org
Amorphous materials do have band structures (another example: liquid metals). It's necessary to have bands in order to accommodate the electrons of the material (they can't all occupy states of the same energy, due to the exclusion principle). However, the electronic states can't be described using Brillouin zone concepts.
 
Can anyone point me to a reference to derive band structure based on disordered/amorphous solids?

All the approaches I have seen - Kronig Penney model, Bloch wavefunctions, Wannier functions, seem to all require periodic lattices...

How can you predict the band structure for a disordered solid? Does it just have a uniform band structure with radial k_r rather than k_x?
is the tight-binding model relevant?
 
Amorphous materials have a band structure, but it is not a nice, clean band structure with sharp energies. Rather, it results from the fact that locally the amorphous material has more or less the same first-neighbor bonds as the crystalline material, the second neighbors are somewhat similar, and the mess starts from there on.

Amorphous materials are isotropic, so the band structure should also be isotropic, i.e. only depend on k_r as you point out.
 
Strictly speaking, non-periodic materials do not have a band structure. Having a band structure means that electronic states can be classified according to k-vectors. k-vectors are the labels of the irreducible representations of the lattice translation group. While in an amorphous system of course you can still define k-vectors, if the Hamiltonian H does not commute with lattice translations T, in general H and T cannot be diagonalized by a common set of eigenvectors (with T's eigenvectors being labelled by k and H's by E(k)).
 

Thread 'Stability of persistent currents in superconductors regardless of temperature'

From the BCS theory of superconductivity is well known that the superfluid density smoothly decreases with increasing temperature. Annihilated superfluid carriers become normal and lose their momenta on lattice atoms. So if we induce a persistent supercurrent in a ring below Tc and after that slowly increase the temperature, we must observe a decrease in the actual supercurrent, because the density of electron pairs and total supercurrent momentum decrease. However, this supercurrent...
View full post »

Thread 'Instantaneous dipole moment and orbitals'

Hi. I have got question as in title. How can idea of instantaneous dipole moment for atoms like, for example hydrogen be consistent with idea of orbitals? At my level of knowledge London dispersion forces are derived taking into account Bohr model of atom. But we know today that this model is not correct. If it would be correct I understand that at each time electron is at some point at radius at some angle and there is dipole moment at this time from nucleus to electron at orbit. But how...
View full post »

Similar threads

A Silicon band structure for both ibrav 0 and ibrav 2
Replies
1
Views
3K
B How does lattice vibration affect electron mobility in semiconductor?
Replies
1
Views
1K
A Electronic band structure of iron superconductor BaFe2As2
Replies
4
Views
3K
A Green's function calculation of an infinite lattice with periodicity in 1D
Replies
1
Views
2K
I Are the electrons in the conduction band completely free?
Replies
11
Views
4K
Band Structure of a solid is not related to the size/doping?
Replies
4
Views
3K
I Question about Electronic Band Structure
Replies
3
Views
2K
I Fe Lattice: Band Structure & Fermi Surface Location
Replies
1
Views
2K
Dielectric function with band theory
Replies
3
Views
2K
Mastering DFT: Calculating Band Structures for Heterostructures
Replies
2
Views
4K

Hot Threads

Recent Insights

Back
Top