4 Jump to... processes done on a gas. Starting at the origin to point 1, the...
The figure below is a pressure versus volume graph where the different curves represent different processes done on a gas. Starting at the origin to point 1, the pressure and volume are increased to 2972 Pa and 3.74 m3 respectively. From 1 to 2 the gas expands at constant pressure to a volume of 6.74 m3. From 2 to 3 the pressure rises to 4246 Pa. And finally from 3 to 4 the gas expands again to 10.34 m3. Using...
The figure below is a pressure versus volume graph where the different curves represent different processes done on a gas. Starting at the origin to point 1, the pressure and volume are increased to 2972 Pa and 3.74 m3 respectively. From 1 to 2 the gas expands at constant pressure to a volume of 6.74 m3. From 2 to 3 the pressure rises to 4246 Pa. And finally from 3 to 4 the gas expands again to 10.34 m. Using...
The figure below is a pressure versus volume graph where the different curves represent different processes done on a gas. Starting at the origin to point 1, the pressure and volume are increased to 2559 Pa and 3.74 m3 respectively. From 1 to 2 the gas expands at constant pressure to a volume of 6.74 m3 From 2 to 3 the pressure rises to 4.000 10 Pa. And finally from 3 to 4 the gas expands again to 11.19 m3...
Consider a pressure versus volume graph, where the different curves represent different processes done on a gas. Starting at the origin to point 1, the pressure and volume are increased to 2.500 x 103 Pa and 3.74 m3, respectively From 1 to 2, the gas expands at constant pressure to a volume of 6.74 m3. From 2 to 3, the pressure rises to 4.000 x 103 Pa. Finally, from 3 to 4, the gas expands again to 11.19 m3 Rank...
The figure below is a pressure versus volume graph where the different curves represent different processes done on a gas. Starting at the origin to point 1, the pressure and volume are increased to 2677 Pa and 3.91 m3 respectively. From 1 to 2 the gas expands at constant pressure to a volume of 6.91 m3. From 2 to 3 the pressure rises to 4328 Pa. And finally from 3 to 4 the gas expands again to 10.00 m3. Using...
A sample of gas expands from 2.0 m3 to 8.0 m3 while its pressure decreases from 8.0 Pa to 2.0 Pa. How much work is done by the gas if its pressure changes with volume via each of the three paths shown in the figure?
An ideal gas undergoes two processes. In the first one, the volume remains constant at 0.20 m3 and the pressure increases from 9.0x104 Pa to 7.0x105 Pa. In the second one, the gas is compressed from 0.20 m3 to 0.12 m3 at a constant pressure of 7.0x105 Pa. Calculate the total work done on the gas. a. - 48.0 kJ b. - 56.0 kJ c. - 64.0 kJ d. - 72.0 kJ e. None of the above
The figures show the PV (pressure versus volume) graphs of two processes represented by straight lines The area under the curve equals the work. If volume Vinceases (V > V:) in a process, work W is positive. If volume V deceases (V <V) in a process, work W is negative. Case 1: In the left figure, pressure PA = 4.60 X 106 Pa. pressure P. = 14.72x 106 Pa. Volume VA = 0.0016 m, VA = 0.0048 m3. Don't use...
An ideal gas expands isobarically from point 1 to point 2 as illustrated in the figure below 0 0 V2 0 Vl If the work done by the gas w=26711), initial temperature T=225.6K, n=5.0mols, and initial volume И=1.9m, what is the final volume ½? Answer in cubic meters
The state of an ideal gas can be represented by a point on a PV (pressure-volume) diagram. If you know the quantity of gas, n, a unique point in pressure (P) and volume (V) can be used to determine a temperature (T). Each point on a PV diagram also has a single internal energy (U) assigned to it. If a process starts at a point and returns to that same point on a PV diagram, it returns to the same...