1) Derive an expression for the volume of the reciprocal cell volume in terms of the...

look up the a_j for the bcc and fcc lattices. (1) show that the reciprocal lattice...

look up the a_j for the bcc and fcc lattices. (1) show that the reciprocal lattice of the bcc lattice is fcc and vice versa. (2) for both bcc and fcc work out the magnitude of A_j in terms of a, the edge of the conventional cubic unit cell. bcc: a1=(a/2)(-e1+e2+e3), a2=(a/2)(e1-e2+e3), a3=(a/2)(e1+e2-e3) fcc: a1=(a/2)(e2+e3), a2=(a/2)(e1+e3), a3=(a/2)(e1+e2)

Derive an expression for β = 1/V(∂V/∂T)P for such a gas in terms of b(T) ,...

Derive an expression for β = 1/V(∂V/∂T)P for such a gas in terms of b(T) , db(T)/dT , P , and Vm . Express your answer in terms of the variables b(T) , db(T)/dT , P , and Vm .

Derive an expression that relates the surface area (SA) of a cylinder to the volume (V)...

Derive an expression that relates the surface area (SA) of a cylinder to the volume (V) of a cylinder (i.e., SA:V). Then derive an expression that relates the SA:V of one cylinder to that of another cylinder and use this relationship to compare the SA:V of a ~cylinder-shaped Escherichia coli to the SA:V of a ~cylinder-shaped Bacillus megaterium. E. coli is 2 μm in length and 0.5 μm in diameter whereas B. megaterium is 4 μm in length and 1.5...

Metallic lithium has a bcc crystal structure. Each unit cell is a cube of side length...

Metallic lithium has a bcc crystal structure. Each unit cell is a cube of side length (a) For a bcc lattice, what is the number of atoms per unit volume? Give your answer in terms of a. (Hint: How many atoms are there per unit cell?) (b) Use the result of part (a) to calculate the zero-temperature Fermi energy for metallic lithium. Assume there is one free electron per atom.

Derive the expression for work done by expanding a van der Waal's system. Express the relationship:...

Derive the expression for work done by expanding a van der Waal's system. Express the relationship: a) in terms of volume b) in terms of pressure c) Calculate the work done by isothermal expansion of a van der Waals gas from 1 L to 2 L, and compare the result to the work done in an ideal system. Comment on why the values are different.

1. In the space below, a. state Archimedes’ Principle b. define density c. Mathematically, derive an...

1. In the space below, a. state Archimedes’ Principle b. define density c. Mathematically, derive an equation based on this laboratory that uses Archimedes principle to measure the density of an object in terms of measurable quantities. Make sure the density of the object is NOT in terms of the unknown volume of the object in question. You can assume you know the density of water. d. Be sure to draw a free-body diagram of the mass attached to the...

Consider a free fermion gas of N particles in a volume V at zero temperature. The...

Consider a free fermion gas of N particles in a volume V at zero temperature. The total kinetic energy of the gas is U = (3/5)N epsilon-F with epsilon-F = (hbar^2/2m)((3(π^2)N)/V )^ 2/3 . (a) Using the thermodynamic identity show that the pressure of the gas is given by p = − (∂U/∂V )σ,N . (b) Derive an expression of the degenerated-gas pressure and express your final result in terms of U and V .

1)Write down the coordinate free definition of divergence of a vector field. 2)Derive an expression for...

1)Write down the coordinate free definition of divergence of a vector field. 2)Derive an expression for the divergence of a vector field using part 1) and using integral form of Gauss' law for the electric field E.

1. Convert the three Bravais lattices defined in real space: Simple Cubic, Body-Centered Cubic, and Face-Centered...

1. Convert the three Bravais lattices defined in real space: Simple Cubic, Body-Centered Cubic, and Face-Centered Cubic unit cells to reciprocal space latice. 2. Describe in detail what the converted reverse space latice, such as question 1, means, and mention the importance in semiconductor materials.

Q.1     (1) For one mol of a monoatomic ideal gas in thermal equilibrium derive an expression...

Q.1     (1) For one mol of a monoatomic ideal gas in thermal equilibrium derive an expression for the total kinetic energy of all molecules as a function of temperature. Assume three degrees of freedom for each molecule due to translational motion. Explain how your result is related to the equipartition theorem.