Using Exponentials and Logarithms, show that T2/T1 =(V1/V2)k-1 where p is pressure T is temperature and...

In the initial state, an ideal gas has pressure p1, volume V1 and temperature T1. Now...

In the initial state, an ideal gas has pressure p1, volume V1 and temperature T1. Now the gas changes its state by effecting a state change so that it reaches the pressure p2, the volume V2 and the temperature T2 in the new state. The pressure doubles during this state change, which is an isochore process. a) Find the work W performed during the isochore process. b) The heat Q is exchanged between the gas and the surroundings during the...

Let H=Span{v1,v2} and K=Span{v3,v4}, where v1,v2,v3,v4 are given below. v1 = [3 2 5], v2 =[4...

Let H=Span{v1,v2} and K=Span{v3,v4}, where v1,v2,v3,v4 are given below. v1 = [3 2 5], v2 =[4 2 6], v3 =[5 -1 1], v4 =[0 -21 -9] Then H and K are subspaces of R3 . In fact, H and K are planes in R3 through the origin, and they intersect in a line through 0. Find a nonzero vector w that generates that line. w = { _______ }

When gas expands in a cylinder with radius r, the pressure P at any given time...

When gas expands in a cylinder with radius r, the pressure P at any given time is a function of the volume V: P = P(V). The force exerted by the gas on the piston (see the figure) is the product of the pressure and the area: F = πr2P. The work done by the gas when the volume expands from volume V1 to volume V2 is W = V2 P dV V1 . In a steam engine the pressure...

Two flasks have the same gas at the same initial temperature T and pressure P. The...

Two flasks have the same gas at the same initial temperature T and pressure P. The volume V1 of the flask #1 is much bigger than the volume V2 of the second flask (V1>V2). The flasks are connected by a narrow glass tube which has a drop of liquid mercury. Because the pressure in each flask is the same, the drop of mercury is at equilibrium exactly in the middle of the glass tube. Would the drop of mercury move...

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...

1. A sample of gas in a balloon has an initial temperature of 40. ∘C and...

1. A sample of gas in a balloon has an initial temperature of 40. ∘C and a volume of 1.88×103 L . If the temperature changes to 84 ∘C , and there is no change of pressure or amount of gas, what is the new volume, V2, of the gas? 2.   What Celsius temperature, T2, is required to change the volume of the gas sample in Part A (T1 = 40. ∘C , V1= 1.88×103 L ) to a volume...

TABLE1 V1 (mL) P1 (kPa) V2 (mL) P2 (kPa) Run1 40 98.5 21 183.1 Run2 40...

TABLE1 V1 (mL) P1 (kPa) V2 (mL) P2 (kPa) Run1 40 98.5 21 183.1 Run2 40 97.3 21 183.0 Run3 40 98.7 21 182.7 Run4 40 98.7 21 181.5 Run5 40 98.1 21 183.9 Avg 40 98.26 21 182.92 1. From your average experimental values, caluclate the two ratios, V1/V2 and P2/P1. Show work. (It is just asking me to divide V1 by V2? and P2 by P1???????) 2. Calculate the Standard Errors for P1 and P2 from Table 1....

One mole of air is compressed from pressure P1 and temperature T1 at constant volume till...

One mole of air is compressed from pressure P1 and temperature T1 at constant volume till its pressure is doubled. Then it is expanded reversibly and isothermally to the original pressure, and finally restored to the original temperature by cooling at constant pressure. Sketch the path followed by the gas, on a P-V diagram and calculate the net work done by the gas.

#4 A system containing 2.50 moles of an ideal gas for which = 20.79 JK-1mol-1 is...

#4 A system containing 2.50 moles of an ideal gas for which = 20.79 JK-1mol-1 is taken through the following cycles: (1) an isobaric expansion (P1 = 16.6 bar) from V1 = 1.00 L to V2 = 25.0 L; (2) an isochoric cooling from T2 to the original temperature, T1; followed by (3) an isothermal compression (at temperature T1) to the original pressure P1 and volume V1. A. Represent the above processes on a P-V diagram B. Calculate q, w,...

A cylinder fitted with a frictionless, massless piston contains compressed liquid water at a temperature T1=20C....

A cylinder fitted with a frictionless, massless piston contains compressed liquid water at a temperature T1=20C. The atmospheric pressure on the outside of the system is P=1.0 bar. Heat is then added until the water is completely converted to saturated vapor. (a) What are the changes in specific volume, v2-v1 (m3/kg) and internal energy, u2-u1 (kJ/kg) of the water for this process? (b) How much specific work, if any, is done by the system? (c) What is the amount of...