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A flask holds 8.75 kg of a diaatomic ideal gas (mass number of the gas 82,8)....
1 mole, n=1, of an ideal monatomic gas undergoes the
following process: It starts in the state(Po, Vo). It expands
isobarically to the state(Po, 5Vo). It is heated at constant
volume(isochorically) to (7Po, 5Vo)
A.) Plot this on a PV diagram
B.) What is the temperature difference between the initial and the
final state?
C.) What is the internal energy change?
D.) What is the total heat flow into the gas?
1 mole , n l, of an idcal monatomic...
Part A:Refer to diagram 2. A flask contains 85.2 moles of a
monatomic ideal gas at pressure 6.9 atm and volume 13.4 liters
(point A on the graph. Now, the gas undergoes a cycle of three
steps: - First there is an isothermal expansion to pressure 3.65
atm (point B on the graph). - Next, there is an isochoric process
in which the pressure is raised to P1 (point C on the graph). -
Finally, there is an isobaric compression...
A rigid container holds 4.00 mol of a monatomic ideal gas that has temperature 300 K. The initial pressure of the gas is 6.00 * 104 Pa. What is the pressure after 6000 J of heat energy is added to the gas?
please answer step by step clearly:
You have 12.0 mol of a diatomic ideal gas at 300 K, and 4.00 kJ of heat to add to it. You can choose to heat it isochorically or isobarically. Which of these two methods will result in a higher final temperature, and what will that final temperature be in Kelvin?
In this problem, 1.20 mole of a monatomic ideal gas is initially at 318 K and 1 atm. (a) What is its initial internal energy? kJ (b) Find its final internal energy and the work done by the gas when 480 J of heat are added at constant pressure. final internal energy kJ work done by the gas kJ (c) Find the same quantities when 480 J of heat are added at constant volume. finale internal energy kJ work done...
A container holds 4.5 mol of an ideal monatomic gas with a pressure of 125 kPa. The container initially has a volume of 0.10 m3. The gas undergoes an adiabatic expansion until it reaches a volume of 0.3 m3 and a pressure of 20.0 kPa. What is the thermal energy of the gas after the expansion? How much energy went into or out of the gas as work during the expansion? (Positive for energy into the gas, negative for energy...
An ideal monatomic gas undergoes changes in pressure and volume, as shown in the pV diagram below. The initial volume is 0.02 m3 and the final volume is 0.10 m3 20 10 01 (a) Calculate the magnitude, or absolute value, of the Work done on the gas in this process. (Be careful with units. Your answer should be in Joules. 1 atm 1.013x 105 Pa.) (b)The work done ON the gas is: O positive O negative (c) The initial temperature...
Learning Goal Internal Energy of an ideal gas The internal energy of a system is the energy stored in the system. In an ideal gas, the internal energy includes the kinetic energies (translational and rotational) of all the molecules, and other energies due to the interactions among the molecules. The internal energy is proportional to the Absolute Temperature T and the number of moles n (or the number of molecules N). n monatomic ideal gases, the interactions among the molecules...
During an adiabatic process, the temperature of 6.10 moles of a monatomic ideal gas drops from 495 degree C to 147 degree C. Find the work it does. kJ Find the heat it exchanges with the surroundings. kJ Find the change in internal energy. kJ
The temperature of 3.5 mol of a monatomic ideal gas is 320 K. The internal energy of this gas is doubled by the addition of heat. (a) How much heat is needed when it is added at constant volume? (b) How much heat is needed when it is added at constant pressure?