5. Consider a three-dimensional cubic lattice with a lattice constant equal to a. Sketch the following...

Consider a two-dimensional solid measuring LxL in which the atoms are arranged in a square lattice...

Consider a two-dimensional solid measuring LxL in which the atoms are arranged in a square lattice with lattice parameter a. There is only a single atomic species in the solid, and the valence is equal to one, that is, each atom contributes one electron to the electron “sea”. (i) Sketch the reciprocal lattice for this crystal and include units. (ii) Compute the Fermi wave-vector kF. (iii) Make a two-dimensional sketch and indicate, the Fermi circle (i.e. the occupied states at...

A two-dimensional metallic thin film has square shape with dimension L. Assume a cubic lattice with...

A two-dimensional metallic thin film has square shape with dimension L. Assume a cubic lattice with lattice constant a. a) Derive the density of energy state for this 2D material. b) Find Fermi energy at low temperature.

Aluminum is a face-centred cubic structure with a lattice constant of a = 4.05 ˚A. If...

Aluminum is a face-centred cubic structure with a lattice constant of a = 4.05 ˚A. If incoming radiation has a wavelength of 1.5 ˚A, identify which reflections you will see and at which angles 2θ for a powder diffraction experiment. You may use Bragg’s Law along with the formula d(hk`) = a √ h 2 + k 2 + ` 2 (1) (the n in Bragg’s law is incorporated into the values for hk`) I recommend using a spread sheet...

Consider a simple cubic with a 6.0 Å lattice constant. The measurements of X-ray scattering from...

Consider a simple cubic with a 6.0 Å lattice constant. The measurements of X-ray scattering from the powder sample are carried out with a 1.5 Å X-ray source. (a) Using the diffraction condition relating G (a reciprocal lattice vector), k (the wave vector of the incident X-ray), and k' (the wave vector of the scattered X-ray) derive a relationship between |G|, |k|, and the scattering angle θ. (b) Write a symbolic expression for |G|. (c) Use the results of parts...

Iron (Fe) crystallizes in a body-centered cubic structure with a lattice constant of 0.287 nm: Use...

Iron (Fe) crystallizes in a body-centered cubic structure with a lattice constant of 0.287 nm: Use drawing to show how the iron atoms are packed in the unit cell. How many iron atoms are contained in each unit cell?         Use drawings to show how the iron atoms are arranged on the (100) and (110) planes.                    Determine the density of iron (g/cm3) by dividing the total mass of iron atoms in the unit cell by the volume of the unit cell....

Iron (Fe) crystallizes in a body-centered cubic structure with a lattice constant of 0.287 nm: a....

Iron (Fe) crystallizes in a body-centered cubic structure with a lattice constant of 0.287 nm: a. Use drawing to show how the iron atoms are packed in the unit cell. How many iron atoms are contained in each unit cell?         b. Use drawings to show how the iron atoms are arranged on the (100) and (110) planes.        c. Determine diameter of iron atom    d. Determine the density of iron (g/cm3) by dividing the total mass of iron atoms in...

Iron (Fe) crystallizes in a body-centered cubic structure with a lattice constant of 0.287 nm: a....

Iron (Fe) crystallizes in a body-centered cubic structure with a lattice constant of 0.287 nm: a. Use drawing to show how the iron atoms are packed in the unit cell. How many iron atoms are contained in each unit cell?         b. Use drawings to show how the iron atoms are arranged on the (100) and (110) planes.        c. Determine diameter of iron atom    d. Determine the density of iron (g/cm3) by dividing the total mass of iron atoms in...

Solid State Physics Consider a one-dimensional (1-D) atomic lattice with an interatomic spacing of 5 angstroms...

Solid State Physics Consider a one-dimensional (1-D) atomic lattice with an interatomic spacing of 5 angstroms (Å). Each atomic site can be represented by a rectangular-shaped potential well of 1 eV depth and width of 1 angstrom (Å). Estimate the following parameters: The width of the 2nd lowest energy band (in eV).

Solid State Physics Consider a one-dimensional (1-D) atomic lattice with an interatomic spacing of 5 angstroms...

Solid State Physics Consider a one-dimensional (1-D) atomic lattice with an interatomic spacing of 5 angstroms (Å). Each atomic site can be represented by a rectangular-shaped potential well of 1 eV depth and width of 1 angstrom (Å). Estimate the following parameter: The lowest energy (in eV) at which an electron starts to behave as a hole.

Consider a simple cubic lattice of volume, L3 , where there are N1, N2, N3, atoms...

Consider a simple cubic lattice of volume, L3 , where there are N1, N2, N3, atoms along the x, y, z coordinates, respectively. Derive the following expression for the density of allowed travelling wave vibrational modes,