A 59.1 liter container holds 8.74 kg of a diatomic ideal gas (mass number of the...

A 29.8 liter container holds 4.71 kg of a diatomic ideal gas (mass number of the...

A 29.8 liter container holds 4.71 kg of a diatomic ideal gas (mass number of the gas 508) at 292 oC . If a piston changes the volume of the gas isothermally to 467 liter, how much heat added or removed during this process, in kJ? A positive answer means heat is added; a negative answer means heat was removed.  

1. A flask holds 9.73 kg of a monatomic ideal gas (mass number 86.4). If the...

1. A flask holds 9.73 kg of a monatomic ideal gas (mass number 86.4). If the gas changes temperature isochorically (constant volume) from temperature 802o C to 376o C, find the change in the internal energy of the gas, in kJ. A positive answer means the internal energy increased; a negative answer means the internal energy decreased.   2. A flask holds 2.25 kg of a diatomic ideal gas (mass number of the gas 92.1). If the gas changes temperature isochorically...

3 kg of a monatomic ideal gas (mass number 278), is slowly changed from pressure 36.4...

3 kg of a monatomic ideal gas (mass number 278), is slowly changed from pressure 36.4 atm and volume 973 liters to pressure 49.6 atm and volume 606 liters. The P-V diagram for this process is a straight line. Find the total work done by the system, in KJ.  A positive answer means work is done by the system; a negative answer means work is done on the system.

21.3 moles of a diatomic ideal gas undergo three steps: A to B is an isobaric...

21.3 moles of a diatomic ideal gas undergo three steps: A to B is an isobaric (constant pressure P1 = 4.15x106 Pascal) expansion from volume V1 = 0.0609 m3 to V2 = 0.934 m3. B to C is isochoric (constant volume) C to A is isothermal (constant T). During the isobaric expansion from A to B: find Q, the heat transferred, in Joules. Give your answer in scientific notation. NOTE: A positive sign means heat has been added; a negative...

A container is filled with an ideal diatomic gas to a pressure and volume of P1...

A container is filled with an ideal diatomic gas to a pressure and volume of P1 and V1, respectively. The gas is then warmed in a two-step process that increases the pressure by a factor of five and the volume by a factor of three. Determine the amount of energy transferred to the gas by heat if the first step is carried out at constant volume and the second step at constant pressure. (Use any variable or symbol stated above...

A container is filled with an ideal diatomic gas to a pressure and volume of P1...

A container is filled with an ideal diatomic gas to a pressure and volume of P1 and V1, respectively. The gas is then warmed in a two-step process that increases the pressure by a factor of three and the volume by a factor of two. Determine the amount of energy transferred to the gas by heat if the first step is carried out at constant volume and the second step at constant pressure. (Use any variable or symbol stated above...

14.3 10.0 L of an ideal diatomic gas at 2.00 atm and 275K are contained in...

14.3 10.0 L of an ideal diatomic gas at 2.00 atm and 275K are contained in a cylinder with a piston. The gas first expands isobarically to 20.0 L (step 1). It then cools at constant volume back to 275 K (step 2), and finally contracts isothermally back to 10.0 L (step 3). a) Show the series of processes on a pV diagram. b) Calculate the temperature, pressure, and volume of the system at the end of each step in...

14.3 10.0 L of an ideal diatomic gas at 2.00 atm and 275K are contained in...

14.3 10.0 L of an ideal diatomic gas at 2.00 atm and 275K are contained in a cylinder with a piston. The gas first expands isobarically to 20.0 L (step 1). It then cools at constant volume back to 275 K (step 2), and finally contracts isothermally back to 10.0 L (step 3). a) Show the series of processes on a PV diagram. b) Calculate the temperature, pressure, and volume of the system at the end of each step in...

10.0 L of an ideal diatomic gas at 2.00 atm and 275 K are contained in...

10.0 L of an ideal diatomic gas at 2.00 atm and 275 K are contained in a cylinder with a piston. The gas first expands isobarically to 20.0 L (step 1). It then cools at constant volume back to 275 K (step 2), and finally contracts isothermally back to 10.0 L (step 3). a) Show the series of processes on a pV diagram. b) Calculate the temperature, pressure, and volume of the system at the end of each step in...

A container holds .2610 molea of an unknown blue ideal gas as shown below . the...

A container holds .2610 molea of an unknown blue ideal gas as shown below . the initial temperture of the gas is 302.6k and the pressure is 1.38x10^6pa the gas initially has a volume of 4.800x10^4 m^3. Heat is added to the system causing the gas to expand until volume has tripled . the pressure stays constant as does the number of moles of gas . what is the temperture of system ? During process in part a , the...