Sodium transforms from bcc to hcp at T = 23 K. Assuming the atomic density remains...

Show that in the compact hexagonal structure the theoretical axial relationship is c / a =...

Show that in the compact hexagonal structure the theoretical axial relationship is c / a = 1.633. Sodium transforms from bcc to hcp to 23 K. Assuming that the density remains fixed during the transition, find the network constant of the hexagonal phase, since a = 4.23 A in the cubic phase and that the ratio c / a It has the ideal value solid state physics

Calculate the theoretical density of HCP titanium given that titanium has an atomic radius of 0.147...

Calculate the theoretical density of HCP titanium given that titanium has an atomic radius of 0.147 nm and an atomic weight of 47.867. Assume the c/a ratio is 1.633. Please show all work!!! Thank you!

--Given Values-- Atomic Radius (nm) = 0.116 FCC Metal = Gold BCC Metal: = Sodium Temperature...

--Given Values-- Atomic Radius (nm) = 0.116 FCC Metal = Gold BCC Metal: = Sodium Temperature ( C ) = 1017 Metal A = Tin Equilibrium Number of Vacancies (m-3) = 6.02E+23 Temperature for Metal A = 369 Metal B = Gallium 1) If the atomic radius of a metal is the value shown above and it has the face-centered cubic crystal structure, calculate the volume of its unit cell in nm3? Write your answers in Engineering Notation.          ...

A metal has a mass density ρ = 8.95 g/cm3 . Assuming the effective mass of...

A metal has a mass density ρ = 8.95 g/cm3 . Assuming the effective mass of electron in the metal m*=0.5m0. The electron rest mass m0 = 9.11×10-31 kg. The atomic mass is 63.5, Avogadro’s number is 6.022×1023 . The Boltzmann constant kB = 1.38×10-23 J/K = 8.62×10-5 eV/K. The reduced Planck constant ћ = 1.55×10-34 J·s. Calculate the following assuming the periodic boundary condition. (a) the concentration of the conduction electrons (assume that each Copper atom has one electron...

Lead has a fcc lattice of constant a = 0.494 nm. The Young's modulus of elasticity...

Lead has a fcc lattice of constant a = 0.494 nm. The Young's modulus of elasticity for lead is EY = 1.6 · 1010 Nm− 2. If lead melts when the average amplitude of atomic vibrations is 15.8% of the distance between atoms (Lindemann criterion), calculate: (a) The distance of adjacent atoms in the fcc lattice. (b) Calculate the Debye temperature θD for lead if the phase velocity „c“ of phonon propagation for longitudinal and transverse modes in the fcc...

One mole of H2O(l) is compressed from a state described by P =1.00 bar and T...

One mole of H2O(l) is compressed from a state described by P =1.00 bar and T = 350. K to a state described by 515 bar and 795 K . In addition, β=2.07×10−4K−1 and the density can be assumed to be constant at the value 997 kgm−3 . Calculate ΔS for this transformation, assuming that κ = 0.

The decomposition of HI (g) into its elements in the gas phase at 800 K is...

The decomposition of HI (g) into its elements in the gas phase at 800 K is found to proceed by a second order process. A) Please write a balanced equation for the reaction (smallest integer ratio of coefficients, please). B) Please write the rate law for the reaction: C) Given that it takes 142 s for the [HI (g)] to change from 6.75 x 10-2 M to 3.50 x 10-2 M, please calculate the value of the rate constant (and...

Thermodynamics: Consider the equilibrium reaction A(g) + B(g) -><- C(g)+D(g). At T=298 K, the standard enthalpies...

Thermodynamics: Consider the equilibrium reaction A(g) + B(g) -><- C(g)+D(g). At T=298 K, the standard enthalpies of formation of the components in the gas phase are -20, -40, -30, and -10 kJ/mol for A,B,C, and D, respectively. The standard-state entropies of the components in the gas phase are 30, 50, 50, and 80 J/(mol K), in the same order. The vapor pressure of liquid C at this temperature is 0.1 bar, while all other components are volatile gases with Henry's...

A sample containing 2.50 moles of He (1 bar, 345 K ) is mixed with 1.75...

A sample containing 2.50 moles of He (1 bar, 345 K ) is mixed with 1.75 mol of Ne (1 bar, 345 K ) and 1.50 mol of Ar (1 bar, 345 K ). Calculate ΔGmixing. Calculate ΔSmixing. Express your answer with the appropriate units. Calculate ΔA for the isothermal compression of 3.11 mol of an ideal gas at 321 K from an initial volume of 60.0 L to a final volume of 20.5 L.​ Does it matter whether the...

Data for carbon dioxide: Molecular weight:44.0 Heat capacity of gas phase: 0.036+4.23 x10-5T   (in kJ/moleoC, T is...

Data for carbon dioxide: Molecular weight:44.0 Heat capacity of gas phase: 0.036+4.23 x10-5T   (in kJ/moleoC, T is in oC) Viscosity                                 Pr                    k (W/m K) 180oC2.13 x10-5kg/(m s)                  0.721               0.029 130oC  1.93x10-5kg/(m s)                  0.738               0.025   80oC  1.72x10-5kg/(m s)                  0.755               0.020 Approximate density: 2.0 kg/m3 Data for water: Molecular weight:18.0 Heat capacity for liquid water: 0.0754 kJ/mole oC   Viscosity: Viscosity                                 Pr                    k (W/m K) 180oC139 x10-6kg/(m s)                   0.94                 0.665 130oC  278x10-6kg/(m s)                   1.72                 0.682   80oC  472x10-6kg/(m s)                   3.00                 0.658 Ideal gas constant: 0.08206 L atm/(mol K) Carbon dioxide, with flow rate of 0.10 kg/s, is to be cooled from 180 oC to 80...