In thermodynamics, what is ideal gas heat capacity? How is it derived and applicable to the...

The heat capacity at constant volume of an ideal gas depends on: Select one: a. The...

The heat capacity at constant volume of an ideal gas depends on: Select one: a. The number of molecules b. Temperature c. None of the options shown d. The volume e. The pressure

Consider 14.61 moles of an ideal diatomic gas. (a) Find the total heat capacity of the...

Consider 14.61 moles of an ideal diatomic gas. (a) Find the total heat capacity of the gas at (i) constant volume and (ii) constant pressure assuming that the molecules translate and vibrate but do not rotate. Be sure to clearly explain how the equipartition of energy is used to solve this problem. (b) Repeat problem (a) above except assume that the molecules translate, rotate and vibrate.

The heat capacity of a diatomic gas is greater than the heat capacity of a monatomic...

The heat capacity of a diatomic gas is greater than the heat capacity of a monatomic gas. Explain.

1. (a) State the First Law of Thermodynamics. (b) Derive a simple relation: Cp - Cv...

1. (a) State the First Law of Thermodynamics. (b) Derive a simple relation: Cp - Cv = R, between the molar heat capacity at constant pressure Cp and the molar heat capacity at constant volume Cv for an ideal gas, as shown in class. Can you explain why Cp > Cv.

The heat capacity at constant pressure of a certain amount of a diatomic gas is 13.2...

The heat capacity at constant pressure of a certain amount of a diatomic gas is 13.2 J/K. (a) Find the number of moles of the gas. (b) What is the internal energy of the gas at T = 312 K? (c) What is the molar heat capacity of this gas at constant volume? (d) What is the heat capacity of this gas at constant volume?

The heat capacity at constant pressure of a certain amount of a diatomic gas is 13.2...

The heat capacity at constant pressure of a certain amount of a diatomic gas is 13.2 J/K. (a) Find the number of moles of the gas. (b) What is the internal energy of the gas at T = 312 K? (c) What is the molar heat capacity of this gas at constant volume? (d) What is the heat capacity of this gas at constant volume?

A 2.0 mol sample of ideal gas with molar specific heat Cv = (5/2)R is initially...

A 2.0 mol sample of ideal gas with molar specific heat Cv = (5/2)R is initially at 300 K and 100 kPa pressure. Determine the final temperature and the work done on the gas when 1.6 kJ of heat is added to the gas during each of these separate processes (all starting at same initial temperature and pressure: (a) isothermal (constant temperature) process, (b) isometric (constant volume) process, and (c) isobaric (constant pressure) process. Hint: You’ll need the 1st Law...

1. One mole of an ideal monatomic gas is confined to a rigid container. When heat...

1. One mole of an ideal monatomic gas is confined to a rigid container. When heat is added reversibly to the gas, its temperature changes from 300 K to 350K. (a) How much heat is added? (b) What is the change in entropy of the gas?

The heat capacity at constant volume of a certain amount of a monatomic gas is 53.7...

The heat capacity at constant volume of a certain amount of a monatomic gas is 53.7 J/K. (a) Find the number of moles of the gas. in mol (b) What is the internal energy of the gas at T = 286 K? in kJ (c) What is the heat capacity of the gas at constant pressure? in J/k

1) An isentropic flow: a) has no heat transfer, b) does not allow temperature to change,...

1) An isentropic flow: a) has no heat transfer, b) does not allow temperature to change, c) can occur in a real physical problem, d) can only occur when the fluid is at rest. 2) Based on the first law of thermodynamics (assuming no chemical reactions, i.e. just a simple gas like air or helium): a) changing the flow velocity can heat the flow, b) moving a solid body through a fluid can heat the fluid, c) compressing a perfectly...