The multiplicity of a system Ω = ??b where ? and ? are positive constants and...

You are given an ideal gas which undergoes a process where the internal energy U is...

You are given an ideal gas which undergoes a process where the internal energy U is a function of the volume, V according to U = bV^ f , where b and f are known constants. You know the ratio of specific heats, γ. (a) Suppose the internal energy is increase by a finite amount ∆. What work is performed by the gas. (b) What amount of heat is transferred to the gas in the situation (a). (c) What is...

Positive non-conservative work | Problem In a system where positive non-conservative work is being down on...

Positive non-conservative work | Problem In a system where positive non-conservative work is being down on the system, which of the following statements are necessarily true? If the kinetic energy is decreasing, the potential energy must be increasing by the same amount. If the kinetic energy is decreasing, the potential energy must be increasing by a larger amount. If the kinetic energy is increasing, the potential energy must be decreasing. If the kinetic energy is constant, the potential energy must...

A gaseous system releases 14 J of heat and increases its internal energy by 16 J....

A gaseous system releases 14 J of heat and increases its internal energy by 16 J. Which of the following statements is correct? The volume of the system decreases and a positive amount of work is done. The volume of the system increases and a negative amount of work is done. The volume of the system increases and a positive amount of work is done. The volume of the system decreases and a negative amount of work is done. The...

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?

It runs under standard air assumptions with variable specific heat, runs in a closed system, and...

It runs under standard air assumptions with variable specific heat, runs in a closed system, and consists of the following 4 processes: 4-1: Isentropic compression of 100kPa and 22ºC up to 600kPa 1-2: Adding heat up to 1500K (at constant volume) 2-3: Isentropic expansion down to 100kPa 3-4: Heat rejection (at constant pressure) a) Calculate the net output work (in kJ / kg) b) Determine the thermal efficiency of the system (Expressed in%) c) Plot the cycle on your "P-v"...

Consider the following four-process cycle that is carried out on a system of monatomic ideal gas,...

Consider the following four-process cycle that is carried out on a system of monatomic ideal gas, starting from state 1 in which the pressure is 88.0 kPa and the volume is 3.00 liters. Process A is an isothermal process that triples the volume; process B is a constant volume process that returns the system to a pressure of 88.0 kPa; process C is an isothermal process that returns the system to a volume of 3.00 liters; and process D is...

a) The function f(x)=ax^2+8x+b, where a and b are constants, has a local maximum at the...

a) The function f(x)=ax^2+8x+b, where a and b are constants, has a local maximum at the point (2,15). Find the values of a and b. b) if b is a positive constand and x> 0, find the critical points of the function g(x)= x-b ln x, and determine if this critical point is a local maximum using the second derivative test.

Consider a system containing permanent electric dipoles Pe. The infinitesimal work done on the system in...

Consider a system containing permanent electric dipoles Pe. The infinitesimal work done on the system in increasing an applied electric field Ee is given as dW = -VPedEe , where V is the volume of the system (assuming V keeps constant). (a) Analogy with the magnetic systems, please obtain the fundamental relation for such system of electric dipoles from the first law. (b) Use this fundamental relation to determine the infinitesimal changes of thermodynamic potentials, i.e., dE, DH, DF, and...

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