An ideal gas is brought through an isothermal compression process. The 3.00 mol3.00 mol of gas...

An ideal gas is brought through an isothermal compression process. The 2.00 moles of gas go...

An ideal gas is brought through an isothermal compression process. The 2.00 moles of gas go from having an initial volume of 219.8 cm3 to 120.5 cm3. If 2182 cal are released by the gas during this process, what are the temperature T of the gas and the final pressure pf?

An ideal gas is brought through an isothermal compression process. The 4.00 mol of gas goes...

An ideal gas is brought through an isothermal compression process. The 4.00 mol of gas goes from an initial volume of 259.4×10−6 m3 to a final volume of 110.6×10−6 m3 . If 8070 J is released by the gas during this process, what are the temperature ? and the final pressure ?? of the gas? ?= K ?f= Pa

a.) In an Isothermal process the temperature stays thes same as the volume and pressure are...

a.) In an Isothermal process the temperature stays thes same as the volume and pressure are allowed to change. In such a proces the work is found by W=nRTln (VfVi), with n as the number of moles, R as the constant 8.31 J/mole*K . How much work is done in an isothermal process of an ideal gas starting at a pressure of 2.10E2 kPa, and 0.0360 m3 volume as it expands to a volume of 0.165 m3? b.) If the...

A vessel with a movable piston contains 1.90 mol of an ideal gas with initial pressure...

A vessel with a movable piston contains 1.90 mol of an ideal gas with initial pressure Pi = 2.03 ✕ 105 Pa, initial volume Vi = 1.00 ✕ 10−2 m3, and initial temperature Ti = 128 K. (a) What is the work done on the gas during a constant-pressure compression, after which the final volume of the gas is 2.50 L? J (b) What is the work done on the gas during an isothermal compression, after which the final pressure...

In an Isothermal process the temperature stays thes same as the volume and pressure are allowed...

In an Isothermal process the temperature stays thes same as the volume and pressure are allowed to change. In such a proces the work is found by W=nRTln (VfVi), with n as the number of moles, R as the constant 8.31 J/mole*K . How much work is done in an isothermal process of an ideal gas starting at a pressure of 225 kPa, and 0.0370 m3 volume as it expands to a volume of 0.199 m3?     If the gas...

In class we discussed a reversible, isothermal compression of an ideal gas. The initial point (1)...

In class we discussed a reversible, isothermal compression of an ideal gas. The initial point (1) is an ideal gas in equilibrium at pressure 1 (P1), volume 1 (V1) and temperature (T), and the final point (2) is an ideal gas in equilibrium at pressure 2 (P2), volume 2 (V2) and temperature (T), where V2 d) For each differential step, the change in entropy is given by dS=qrev/T =!!!"#! . Since T is constant , this express ion can be...

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 0.505-mol sample of an ideal diatomic gas at 408 kPa and 309 K expands quasi-statically...

A 0.505-mol sample of an ideal diatomic gas at 408 kPa and 309 K expands quasi-statically until the pressure decreases to 150 kPa. Find the final temperature and volume of the gas, the work done by the gas, and the heat absorbed by the gas if the expansion is the following. (a) isothermal final temperature K volume of the gas L work done by the gas J heat absorbed J (b) adiabatic final temperature K volume of the gas L...

One mole of an ideal gas does 3000 J of work on its surroundings as it...

One mole of an ideal gas does 3000 J of work on its surroundings as it expands isothermally to a final pressure of 1.00 atm and volume of 25.0 L. Determine: a) the initial volume ? b) the temperature of the gas? (Note: 1 atm = 1.01 x 105Pa, universal gas constant R = 8.31 J/mol K, 1 L = 10-3m3)

n = 3.50 mol of Hydrogen gas is initially at T = 310 K temperature and...

n = 3.50 mol of Hydrogen gas is initially at T = 310 K temperature and pi = 3.22×105 Pa pressure. The gas is then reversibly and isothermally compressed until its pressure reaches pf = 7.51×105 Pa. What is the volume of the gas at the end of the compression process??