Consider a one-dimensional ideal gas consisting of N = 5 particles each of which has the...

Two particles approach each other with equal and opposite speed v. The mass of one particle...

Two particles approach each other with equal and opposite speed v. The mass of one particle is m, and the mass of the other particle is nm, where n is just a unitless number. Snapshots of the system before, during, and after the elastic collision are shown above. After the collision the first particle moves in the exact opposite direction with speed 2.40v, and the speed of the second particle is unknown. What is the value of n?

Calculate the probability that a particle in ideal gas has its velocity vector (vx, vy, vz)....

Calculate the probability that a particle in ideal gas has its velocity vector (vx, vy, vz). such that the x− component of its velocity is within the interval 0 < vx < v_ave (where v_ave is the average speed of an ideal monoatomic gas)

Photons are massless light particles and they do not interact with each other. Consider a gas...

Photons are massless light particles and they do not interact with each other. Consider a gas of N photons in volume V at temperature T. The energy e of a photon is related to its momentum p by the equation e = cp, where c is the speed of light. Find the pressure P and the internal energy E of the photon gas in terms of N, V, T, and k. ' Hint: ? = −??????, where the partition function...

Consider a free fermion gas of N particles in a volume V at zero temperature. The...

Consider a free fermion gas of N particles in a volume V at zero temperature. The total kinetic energy of the gas is U = (3/5)N epsilon-F with epsilon-F = (hbar^2/2m)((3(π^2)N)/V )^ 2/3 . (a) Using the thermodynamic identity show that the pressure of the gas is given by p = − (∂U/∂V )σ,N . (b) Derive an expression of the degenerated-gas pressure and express your final result in terms of U and V .

Consider a system of three non-interacting particles confined by a one-dimensional harmonic oscillator potential and in...

Consider a system of three non-interacting particles confined by a one-dimensional harmonic oscillator potential and in thermal equilibrium with a total energy of 7/2 ħw. (a) what are the possible occupation numbers for this system if the particles are distinquishable. (b) what is the most probable energy for a distinquishable picked at random from this system.

Two particles, of mass m and mass nm, undergo a head-on, fully elastic collision. (Here n...

Two particles, of mass m and mass nm, undergo a head-on, fully elastic collision. (Here n is just a unitless number.) Before colliding the particles approach one another with equal speed v. Snapshots of the particles before, during, and after the collision are shown above. After the collision the first particle moves away with speed 2.95v in the exact opposite direction, and the velocity of the second particle is unknown. What is the value of n? Before Collision (m)-><-(nm) Collision...

(i) In a square container of area 0.25m2 there are total of n=1.20x1024 particles present. The...

(i) In a square container of area 0.25m2 there are total of n=1.20x1024 particles present. The mass of each particle is given as 6.67x10-9kg and the velocity is 2 m/s, what will be the pressure generated by all the particles? Also calculate the pressure by a single particle. (ii) In part (i) what is the particle density (p(rho)) (aka gas density)? (iii) If the Temperature of a container is maintained to 300K, what should be the velocity of a particle...

Consider a system consisting of three particles: m1 = 4 kg, 1 = < 11, -6,...

Consider a system consisting of three particles: m1 = 4 kg, 1 = < 11, -6, 12 > m/s m2 = 2 kg, 2 = < -13, 7, -4 > m/s m3 = 3 kg, 3 = < -29, 34, 19 > m/s (a) What is the total momentum of this system? tot = ______ kg · m/s (b) What is the velocity of the center of mass of this system? cm = ______ m/s (c) What is the total...

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?

Consider the Ideal Gas Law, which states that PV = nRT, where P is the pressure,...

Consider the Ideal Gas Law, which states that PV = nRT, where P is the pressure, V is the volume, T is the temperature, and n is the number of moles of a gas sample, and R is a constant. (a) Assume a sample of 1 mole of a gas is in a expandable container where temperature and pressure are allowed to vary. Solve this equation for V = f(P,T). (b) Determine ∂V/dP and interpret the result. In particular, describe...