Part A:See diagram 4. 51.4 moles of a diatomic ideal gas undergo three steps: A to...
Part A:See diagram 4. 51.4 moles of a diatomic ideal gas undergo three steps: A to B is an isobaric (constant pressure P1 = 5.64x106 Pascal) expansion from volume V1 = 0.0854 m3 to V2 = 0.979 m3. B to C is isochoric (constant volume) C to A is isothermal (constant T). Find PC, the pressure at point C, in Pascals. Express in scientific notation.
Part B:See diagram 4.
21.6 moles of a diatomic ideal gas undergo three steps:
- A to B is an isobaric (constant pressure P1 = 4.19x106 Pascal) expansion from volume V1 = 0.0918 m3 to V2= 0.747 m3.
- B to C is isochoric (constant volume)
- C to A is isothermal (constant T).
Find WTOT, the total work done in Joules, in the three steps (from A to B to C to A). Express your answer in scientific notation
HINT: A positive sign means the net work was done by the gas; a negative sign means the net work is done by on the gas.
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Part A:See diagram 4. 51.4 moles of a diatomic ideal gas undergo
three steps: A to...
See diagram 4. 22.8 moles of a diatomic ideal gas undergo three steps: A to B...
See diagram 4.
22.8 moles of a diatomic ideal gas undergo three steps:
A to B is an isobaric (constant pressure P1 = 5.25x106 Pascal)
expansion from volume V1 = 0.0248 m3 to V2 = 0.956 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...
3.1 moles of ideal gas undergo an expansion from V1 = 1.2 m3 to V2 =...
3.1 moles of ideal gas undergo an expansion from V1 = 1.2 m3 to V2 = 1.7 m3 during an isothermal process taking place at T = 25 degree C. Calculate Delta U, Delta H, Q, W when The expansion takes place in The following conditions: A reversible expansion. A rapid non-reversible expansion against a constant surrounding pressure equal to The final pressure of The gas. A free expansion where The gas expands in vacuum against zero external pressure.
Part A:Refer to diagram 2. A flask contains 85.2 moles of a monatomic ideal gas at...
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...
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1.On a pV diagram, draw the path a gas takes as it goes through the following...
1.On a pV diagram, draw the path a gas takes as it goes through the following processes: first it undergoes an isochoric heating process, then that’s followed by an isobaric cooling process, finally it goes back to its original position on the pV diagram by undergoing an isothermal expansion. 2. An ideal gas initially at volume V1, pressure P1, and temperature T1 undergoes an isobaric process that changes its temperature to T2. The gas immediately undergoes an isothermal process that...
400 moles of an ideal monatomic gas are kept in a cylinder fitted with a light...
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12. 1 mole of an ideal gas undergoes an isothermal expansion from V1 = 1.4L followed...
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See diagram 4.
22.8 moles of a diatomic ideal gas undergo three steps:
A to B is an isobaric (constant pressure P1 = 5.25x106 Pascal)
expansion from volume V1 = 0.0248 m3 to V2 = 0.956 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...
3.1 moles of ideal gas undergo an expansion from V1 = 1.2 m3 to V2 = 1.7 m3 during an isothermal process taking place at T = 25 degree C. Calculate Delta U, Delta H, Q, W when The expansion takes place in The following conditions: A reversible expansion. A rapid non-reversible expansion against a constant surrounding pressure equal to The final pressure of The gas. A free expansion where The gas expands in vacuum against zero external pressure.
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...
12. 1 mole of an ideal gas undergoes an isothermal expansion from V1 = 1.4L followed by isobaric compression, p = cst.if P1 = 4.4atm, p2 = 1.7atm → ?- m calculate the work done by gas during the expansion. Express work in J = N·m! • For isothermal processes, AT = 0 T = cst → w=faw=fr&v=/MRT AV 594 Show your work like: `x-int_0^5 v(t)dt rarr x-int_0^5(-4*t)dt=-50 m 13. 1 mole of an ideal gas undergoes an isothermal expansion...
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