Q.1     (1) For one mol of a monoatomic ideal gas in thermal equilibrium derive an expression...

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).

Consider a gas which is not ideal so that molecules do interact with each other. this...

Consider a gas which is not ideal so that molecules do interact with each other. this gas is in thermal equilibrium at the absolute temperature T. suppose that the translational degrees of freedom of this gas can be treated classically. what is the mean kinetic energy of (center-of-mass) translation of a molecule in this gas?

2 Equipartition The laws of statistical mechanics lead to a surprising, simple, and useful result —...

2 Equipartition The laws of statistical mechanics lead to a surprising, simple, and useful result — the Equipartition Theorem. In thermal equilibrium, the average energy of every degree of freedom is the same: hEi = 1 /2 kBT. A degree of freedom is a way in which the system can move or store energy. (In this expression and what follows, h· · ·i means the average of the quantity in brackets.) One consequence of this is the physicists’ form of...

(1) (a) Let’s derive an ideal gas law. Let’s start with a cubic box with side-length...

(1) (a) Let’s derive an ideal gas law. Let’s start with a cubic box with side-length L. Now assume we have a particle traveling perfectly horizontally towards a single wall. When it collides with that wall, it will turn around and hit the wall on the other side. It will continue to bounce back and forth in this way forever. What is the period of this motion? In other words, how much time does it take for the particle to...

Suppose that 4.8 moles of an ideal diatomic gas has a temperature of 1061 K, and...

Suppose that 4.8 moles of an ideal diatomic gas has a temperature of 1061 K, and that each molecule has a mass 2.32 × 10-26 kg and can move in three dimensions, rotate in two dimensions, and vibrate in one dimension as the bond between the atoms stretches and compresses. It may help you to recall that the number of gas molecules is equal to Avagadros number (6.022 × 1023) times the number of moles of the gas. a) How...

Find an expression for the coefficient of thermal expansion 1. for an ideal gas 2. for...

Find an expression for the coefficient of thermal expansion 1. for an ideal gas 2. for van der waals show all your work

A gas of nitrogen molecules is at a temperature of 1000K. In this case molecule has...

A gas of nitrogen molecules is at a temperature of 1000K. In this case molecule has 3 translational, 2 rotational, and 2 vibrational degrees of freedom per molecule, i.e. a total of 7. 1.1. [1pt] What is the root mean square velocity of the gas molecules in [m/s]? ANSWER 1.2. [1pt] What is the total mean thermal energy per molecule in [J]? ANSWER 1.3. [2pt] What is the heat capacitance of the gas per molecule, when the gas is heated...

Under constant pressure, the temperature of 1.70 mol of an ideal monatomic gas is raised 15.5...

Under constant pressure, the temperature of 1.70 mol of an ideal monatomic gas is raised 15.5 K. (a) What is the work W done by the gas? J (b) What is the energy transferred as heat Q? J (c) What is the change ΔEint in the internal energy of the gas? J (d) What is the change ΔK in the average kinetic energy per atom? J

. A container has n = 3 moles of a monoatomic ideal gas at a temperature...

. A container has n = 3 moles of a monoatomic ideal gas at a temperature of 330 K and an initial pressure of three times the atmospheric pressure. The gas is taken through the following thermodynamic cycle: 1.- The gas is expanded isobarically (constant pressure) to Vf = 2.5∙Vi. 2.- The pressure of the gas is decreased isochorically (constant volume) to half of the initial value. 3.- The gas is compressed isobarically back to its initial volume. 4.- The...

Consider a gas in equilibrium with a surface. The surface can adsorb the gas molecules onto...

Consider a gas in equilibrium with a surface. The surface can adsorb the gas molecules onto any of M independent, distinguishable sites (distinguishable because the binding sites are localized to specific parts of the surface). The molecular partition function for an adsorbed molecule is q(T) ≡ exp[−β Asurface]. a) Assume that the adsorbed molecules are independent and use the canonical ensemble for N adsorbed molecules to compute the chemical potential for the molecules on the surface. Remember to include the...