How can the band-gap structure be determined using the E-k graph?

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To determine the band-gap structure using the E-k graph, one must first construct the reciprocal lattice and the first Brillouin zone based on the given real space lattice vectors. The E-k graph can be sketched using k values derived from the lattice vectors, specifically k=(π/a) and k=(π/b). The energy at the midpoint of the band can be calculated using the formula E=((ħ^2 * k^2)/(2*m)), which provides two energy values corresponding to the k values. To find the band-gap energy, the height of the periodic potential barrier must be known, as indicated by the Kronig-Penney model. Understanding these relationships is crucial for accurately determining the band-gap structure.
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Hi all,
If you are given the real space lattice vectors (14 Angstroms in the x-direction and 8 Angstroms wit an angle of 91 degrees between them) and have to draw the reciprocal lattice and the the first Brillouin zone, and then using this data sketch the E-k graph and comment on the band-gap structure.

I can graph the reciprocal lattice and the first Brillouin zone, and I sketched the E-k graph using:
k=(pie/a) and k=(pie/b) where a and b are the real space lattice vectors. From this I can determine the energy of the middle of the band using:

E=((h-bar)^2 *(k)^2/(2*m))
where the two values of k were used, which gave two different energy values. Using this information how do I determine the width of the band gap or its band-gap energy.
 
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Hi,according to the Kronig Penney Model, you should know the height of the periodic potential barrier.
 
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