at 300 k the lattice constant for germaninum a is 3.11å.Calculate the number of Germanium atoms...

Germanium has a lattice constant of 0.565 nm.    a) Draw the portion of the (110) plane...

Germanium has a lattice constant of 0.565 nm.    a) Draw the portion of the (110) plane that resides inside a cubic unit cell flat on the page. Label the lengths of the edges. Show the arrangement of atoms whose centers lie on the plane and label the distances between the centers of the nearest neighbor atoms on the plane. Determine the value of the atomic radius. b) Calculate the planar atomic density of atoms on the (110) plane in atoms/cm2....

Germanium forms a substitutional solid solution with silicon. Compute the weight percent of germanium that must...

Germanium forms a substitutional solid solution with silicon. Compute the weight percent of germanium that must be added to silicon to yield an alloy that contains 4.43 × 1021 Ge atoms per cubic centimeter. The densities of pure Ge and Si are 5.32 and 2.33 g/cm3, respectively. The atomic weights for germanium and silicon are 72.64 and 28.09 g/mol, respectively.

Calculate the number of broken bonds per square centimeter for Ge (which has a diamond cubic...

Calculate the number of broken bonds per square centimeter for Ge (which has a diamond cubic structure except all the atoms are are identical) for the (100) and (111) surfaces. Which surface do you think has the lower surface energy? Why? The lattice constant of Ge is 0.565 nm, and its density is 5.32 g/cm^3.

What is the relation between atomic radius r and lattice constant a in the case of...

What is the relation between atomic radius r and lattice constant a in the case of face- centered cubic (FCC) structure? State the number of atoms in a unit cell for FCC structure and hence deduce the atomic packing factor.

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....

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...

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...

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,

The diffusion process of oxygen in titanium lattice is considered at the temperature T1=300 K. The...

The diffusion process of oxygen in titanium lattice is considered at the temperature T1=300 K. The activation energy is 202 kJ/mole and the exponential factor is 1.6 cm2/s. In what time the temperature should be risen to increase the average penetration depth of oxygen in titanium in 4 times?