A perfect gas has a constant volume molar heat capacity of CV ,m  1.5 R...

The constant-pressure heat capacity of a sample of a perfect gas was found to vary with...

The constant-pressure heat capacity of a sample of a perfect gas was found to vary with temperature according to the expression Cp (J K−1) = 20.17 + 0.4001(T/K). Calculate q, w, ΔU, and ΔH when the temperature is raised from 0°C to 100°C (a) at constant pressure, (b) at constant volume.

The molar heat capacity for carbon monoxide at constant volume is CV,m = 20.17 J/(K·mol). A...

The molar heat capacity for carbon monoxide at constant volume is CV,m = 20.17 J/(K·mol). A 13.00-L fixed-volume flask contains CO(g) at a pressure of 3.00 kPa and a temperature of 25.0 °C. Assuming that carbon monoxide acts as an ideal gas and that its heat capacity is constant over the given temperature range, calculate the change in entropy for the gas when it is heated to 800.0 °C.

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.

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...

28 moles of an ideal gas with a molar specific heat at constant volume of cv=3.2R...

28 moles of an ideal gas with a molar specific heat at constant volume of cv=3.2R is initially in state "A" at pressure 73390 Pa and volume 1.0 m3. The gas then expands isobarically to state "B" which has volume 2.6?3m3. The gas then cools isochorically to state "C". The gas finally returns from state "C" to "A" via an isothermal process. What is the adiabatic constant γ for this gas? What is Q during the expansion from "A" to...

The constant pressure molar heat capacity of cerium is given by the following expression. Cerium is...

The constant pressure molar heat capacity of cerium is given by the following expression. Cerium is a metal (ie solid). Cp = (14.014 + 1.929 x 10-2 T) J K-1 mol-1? (a) Calculate the value of ?H for heating 1 moles of cerium from 25.0 C to 125.0 C (note since Cp is dependent on T, you have to integrate) (b) Explain why Cp might depend on T.

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

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?

You have 1.3 moles of a fictitious ideal gas whose molar specific heat values are Cv...

You have 1.3 moles of a fictitious ideal gas whose molar specific heat values are Cv = 13.43 J/(mol·K) and Cp = 21.74 J/(mol·K). The gas is heated from T = 26.5 °C to T = 120.7 °C at a constant volume of 0.0306 m3 1. How much work is done by the gas? 2. How much thermal energy (heat) flows into the gas? 3. What is the change in the internal energy of the gas?