The partition function for a two-dimensional monatomic gas is ?=?2?????/ℎ^2. Find the internal energy for this...

Here we calculate the partition function, molar translational internal energy, and molar translational entropy of a...

Here we calculate the partition function, molar translational internal energy, and molar translational entropy of a monatomic gas. The single particle translational partition function is qtrans=VΛ3) where Λ is the thermal wavelength and teh entropy is given by the Sackur-Tetrode equation S=N*kB*ln((qtrans*e^5/2)/N). A. Calculate the single particle translational partition function q for neon gas at T=298K and V=22.4L. Assume neon behaves ideally. B. Based on your answer in Part A, calculate the molar translational internal energy of neon at at...

For an ideal monatomic gas, what happens to the internal energy of a system if the...

For an ideal monatomic gas, what happens to the internal energy of a system if the average molecular speed of the gas atoms doubles? ​Select only one. a. The internal energy down by a factor of 2 b. The internal energy remains constant (independent of atom speed) c. The internal energy goes up by a factor of 4 d. The internal energy goes up by a factor of 2 e. The internal energy down by a factor of 4 f....

Show that for a atomic gas in an n-dimensional universe the translation partition function is always...

Show that for a atomic gas in an n-dimensional universe the translation partition function is always a dimensionless quantity? Explain clearly and comment on your answer?

A tank contains one kilomole of a monatomic ideal gas, argon, and has a pressure of...

A tank contains one kilomole of a monatomic ideal gas, argon, and has a pressure of 1 atm and a temperature of 300 K. The mass of an argon atom is 6.63 x 10-26 kg. a.) Calculate the internal energy, U, of the gas in Joules. b.) Calculate the average energy per atom in eV. (1eV = 1.602 x 10-19 J) c.) Calculate the partition function, Z. d.) Calculate the entropy of the assembly, S

Calculate partition function, free energy, thermal energy, entropy, and pressure of monoatomic ideal gas (only translational...

Calculate partition function, free energy, thermal energy, entropy, and pressure of monoatomic ideal gas (only translational motion is present).

An ideal monatomic gas is at 100ºC. By increasing the thermal energy of the gas, the...

An ideal monatomic gas is at 100ºC. By increasing the thermal energy of the gas, the rms speed of the gas gets two times bigger. What is the new absolute temperature? (Select the nearest value)

1. A flask holds 9.73 kg of a monatomic ideal gas (mass number 86.4). If the...

1. A flask holds 9.73 kg of a monatomic ideal gas (mass number 86.4). If the gas changes temperature isochorically (constant volume) from temperature 802o C to 376o C, find the change in the internal energy of the gas, in kJ. A positive answer means the internal energy increased; a negative answer means the internal energy decreased.   2. A flask holds 2.25 kg of a diatomic ideal gas (mass number of the gas 92.1). If the gas changes temperature isochorically...

In this problem, 0.90 mole of a monatomic ideal gas is initially at 285 K and...

In this problem, 0.90 mole of a monatomic ideal gas is initially at 285 K and 1 atm. (a) What is its initial internal energy? _____ kJ (b) Find its final internal energy and the work done by the gas when 420 J of heat are added at constant pressure. final internal energy ________kJ work done by the gas _______kJ (c) Find the same quantities when 420 J of heat are added at constant volume. finale internal energy ________kJ work...

Two sample of monatomic ideal gas are being kept at the same temperature and pressure in...

Two sample of monatomic ideal gas are being kept at the same temperature and pressure in different containers. Container A has twice the volume of container B. What can you say about the internal energy of container A compared to container B? a) The internal energy of container A is more than twice the internal energy of container B. b) The internal energy of both containers is identical. c) The internal energy of container A is twice the internal energy...

2.4 mol of monatomic gas A initially has 4700 J of thermal energy. It interacts with...

2.4 mol of monatomic gas A initially has 4700 J of thermal energy. It interacts with 2.8 mol of monatomic gas B, which initially has 8500 J of thermal energy. Part A Which gas has the higher initial temperature? Gas A. Gas B. SubmitMy AnswersGive Up Correct Part B What is the final thermal energy of the gas A? Express your answer to two significant figures and include the appropriate units. Ef = Part C What is the final thermal...