A mole of two-state systems each has energy difference 2.346 × 10-21 J. 1) What is the...

A mole of two-state systems each has energy difference 2.346 × 10-21 J. 1) At what...

A mole of two-state systems each has energy difference 2.346 × 10-21 J. 1) At what temperature are 90% of the two-state parts in their low-energy states? T90%= K 2) What is the heat capacity at T= 17 K? CV= J/K   3) What is the heat capacity at T= 85 K? CV= J/K 4) What is the heat capacity at T= 170 K? CV= J/K

A mole of two-state systems each has energy difference 2.346 × 10-21 J. 1) At what temperature...

A mole of two-state systems each has energy difference 2.346 × 10-21 J. 1) At what temperature are 90% of the two-state parts in their low-energy states? T90%= K 2) What is the heat capacity at T= 17 K? CV= J/K 3) What is the heat capacity at T= 85 K? CV= J/K 4) What is the heat capacity at T= 170 K? CV= J/K

(a) The molar heat capacity of lead is 26.44 J K-1 mol-1. How much energy must...

(a) The molar heat capacity of lead is 26.44 J K-1 mol-1. How much energy must be supplied (by heating) to 100 g of lead to increase it’s temperature by 10.0°C? (b) The molar heat capacity of sodium is 28.24 J K-1 mol-1. What is its specific heat capacity? (c) The specific heat capacity of copper is 0.384 J K-1 g-1. What is its molar heat capacity?

Two moles of nitrogen are initially at 10 bar and 600 K (state 1) in a...

Two moles of nitrogen are initially at 10 bar and 600 K (state 1) in a horizontal piston/cylinder device. They are expanded adiabatically to 1 bar (state 2). They are then heated at constant volume to 600 K (state 3). Finally, they are isothermally returned to state 1. Assume that N 2 is an ideal gas with a constant heat capacity as given on the back flap of the book. Neglect the heat capacity of the piston/cylinder device. Suppose that...

Find the average energy and the heat capacity at constant volume for a two-state system. Take...

Find the average energy and the heat capacity at constant volume for a two-state system. Take the two energies of the system to be ± ε/2. (b) Show that the result for CV is proportional to 1/T2 for kT >>ε , and that it is of the form CV ≈ (constant/T2 e ^(−ε/kT) at low temperature, kT << ε

. Consider two systems,1and 2,interacting thermally but not mechanically or diffusively. Their initial temperatures are 0...

. Consider two systems,1and 2,interacting thermally but not mechanically or diffusively. Their initial temperatures are 0 ◦C and 50 ◦C, respectively. The heatcapacitiesofsystem1areCV1 =2R,Cp1 =2.8R,andthoseofsystem2 areCV2 =3R,Cp2 =4R; R, the gas constant=8.31 J/(K mole). Find (a) their temperature after reaching equilibrium, (b) the change in entropy of system 1, (c) The change in entropy of the total combined system. (d) Why is one of the heat capacities (CV orCp) irrelevant here?

One mole of ideal gas initially at 300 K is expanded from an initial pressure of...

One mole of ideal gas initially at 300 K is expanded from an initial pressure of 10 atm to a final pressure of 1 atm. Calculate ΔU, q, w, ΔH, and the final temperature T2 for this expansion carried out according to each of the following paths. The heat capacity of an ideal gas is cV=3R/2. 1. A reversible adiabatic expansion.

1. A woman expends 92 kJ of energy in walking a kilometer. The energy is supplied...

1. A woman expends 92 kJ of energy in walking a kilometer. The energy is supplied by the metabolic breakdown of food intake and has a 35 percent efficiency. a) If the woman drives a car over the same distance, how much energy is used if the car gets 8.0 km per liter of gasoline (approximately 20 mi/gal)? The density of gasoline is 0.71 g/mL, and its enthalpy of combustion is 49 kJ/g. b) Compare the efficiencies of the two...

A laser pulse has an energy of 21 J and a beam radius of 2 mm....

A laser pulse has an energy of 21 J and a beam radius of 2 mm. The pulse duration is 15 ns and the energy density is uniformly distributed within the pulse. (a) What is the spatial length of the pulse? m (b) What is the energy density within the pulse? kJ/m3 (c) Find the rms values of the electric and magnetic fields in the pulse. E0 =  MV/m B0 =  T

Please show all steps and explain each step, thanks! The heat capacity of solid lead oxide...

Please show all steps and explain each step, thanks! The heat capacity of solid lead oxide is given by Cp,m = (44.35 + 1.47 x 10^-3 T) in units of J K^-1 mol^-1 Calculate the entropy change that occurs when 1 mole of PbO(s) is cooled from 500 to 300 K.