3.95 moles of an ideal gas are compressed isothermally at a temperature of 18.8∘18.8 ∘ C...

You are given an ideal monatomic gas of N = 1.00 × 1023 atoms at temperature...

You are given an ideal monatomic gas of N = 1.00 × 1023 atoms at temperature T = 300K, and volumeV = 20 L. Find: (a) The pressure in the gas in Pa. (b) The work done in Joules when the gas is compressed slowly and isothermally to half its volume. (c) The change in internal energy of the gas in Joules during process (b). (d) The heat (in J) absorbed or given up by the gas during process (b)....

A monatomic ideal gas containing 7.95 moles at a temperature of 235 K are expanded isothermally...

A monatomic ideal gas containing 7.95 moles at a temperature of 235 K are expanded isothermally from a volume of 1.23 L to a volume of 4.44 L. a) Sketch a P vs.V graph. b) Calculate the work done by the gas. c) Calculate the heat flow into or out of the gas. d) If the number of moles is doubled, by what factors do your answers to parts (b) and (c) change? Explain.

1 mole of a non-ideal gas is compressed isothermally at 100°C from 1 bar to 50...

1 mole of a non-ideal gas is compressed isothermally at 100°C from 1 bar to 50 bar. What are the heat and work needed for this (reversible) compression if the gas conforms to the principle of corresponding states? The critical properties of the non-ideal gas are Tc = 406 K and Pc = 11.3 MPa.

A cylinder contains 1.5 moles of ideal gas, initially at a temperature of 113 ∘C. The...

A cylinder contains 1.5 moles of ideal gas, initially at a temperature of 113 ∘C. The cylinder is provided with a frictionless piston, which maintains a constant pressure of 6.4×105Pa on the gas. The gas is cooled until its temperature has decreased to 27∘C. For the gas CV = 11.65 J/mol⋅K, and the ideal gas constant R = 8.314 J/mol⋅K. 1.Find the work done by the gas during this process. 2.What is the change in the internal (thermal) energy of...

An ideal gas is compressed isothermally in a closed and frictionless piston/cylinder apparatus to 2.5 times...

An ideal gas is compressed isothermally in a closed and frictionless piston/cylinder apparatus to 2.5 times its initial pressure, consuming in the process 2.2 kJ mol−1 of work. Calculate the temperature of the gas inside the cylinder.

Two moles of helium gas initially at 195 K and 0.32 atm are compressed isothermally to...

Two moles of helium gas initially at 195 K and 0.32 atm are compressed isothermally to 1.83 atm. a) Find the final volume of the gas. Assume that helium behaves as an ideal gas. The universal gas constant is 8.31451 J/K

An ideal monatomic gas expands isothermally from 0.600 m3 to 1.25 m3 at a constant temperature...

An ideal monatomic gas expands isothermally from 0.600 m3 to 1.25 m3 at a constant temperature of 730 K. If the initial pressure is 1.02 ? 105 Pa find the following. (a) the work done on the gas J (b) the thermal energy transfer Q J (c) the change in the internal energy J

Exactly 1.27 moles of an ideal gas undergoes an isothermal expansion (T = 259 K) from...

Exactly 1.27 moles of an ideal gas undergoes an isothermal expansion (T = 259 K) from state A to state B and then returns to state A by another process. The volume of the gas in state B is three times its initial volume. (a) For the process AB, find the work done by the gas and its change in entropy. work = J change in entropy = J/K (b) Find the gas's change in entropy for the process BA....

Suppose 4.00 mol of an ideal gas undergoes a reversible isothermal expansion from volume V1 to...

Suppose 4.00 mol of an ideal gas undergoes a reversible isothermal expansion from volume V1 to volume V2 = 8V1 at temperature T = 300 K. Find (a) the work done by the gas and (b) the entropy change of the gas. (c) If the expansion is reversible and adiabatic instead of isothermal, what is the entropy change of the gas?

A cylinder contains an ideal gas at the temperature of 300 K and is closed by...

A cylinder contains an ideal gas at the temperature of 300 K and is closed by a movable piston. The gas, which is initially at a pressure of 3 atm occupying a volume of 30 L, expands isothermally to a volume of 80 L. The gas is then compressed isobarically, returning to its initial volume of 30 L. Calculate the work done by gas: a) in isothermal expansion; b) in isobaric compression, c) in the whole process; and d) Calculate...