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 out of the gas.)
How much energy went into or out of the gas as heat during the expansion? (Positive for energy into the gas, negative for energy out of the gas.)
What is the change in thermal energy of the gas?
A container holds 4.5 mol of an ideal monatomic gas with a pressure of 125 kPa....
A monatomic ideal gas initially fills a container of volume V = 0.15 m3 at an initial pressure of P = 360 kPa and temperature T = 275 K. The gas undergoes an isobaric expansion to V2 = 0.55 m3 and then an isovolumetric heating to P2 = 680 kPa. a) Calculate the number of moles, n, contained in this ideal gas. b) Calculate the temperature of the gas, in kelvins, after it undergoes the isobaric expansion. c) Calculate the...
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...
13.A monatomic ideal gas (N=9.1x1023), undergoes adiabatic expansion. During the expansion, the temperature of the gas decreases from 800.0K to 500.OK. The initial volume of the gas is 0.10 m². a. What is the final volume and pressure of the gas, after expansion? b. What is the change in internal energy of the gas? C. Calculate the work associated with this process.
A0.01 m3 container holds a particular gas at an initial temperature of 283 K. The container undergoes an isobaric process to increase the temperature of the gas, resulting in a final temperature of 323 K What is the final volume of the container after the process completes? 0.0114 m None of the other answers is correct 0.0088 m3 0.0020 m3 0.0500 m Question 2 1 pts A container, of volume 0.025 m3 hold a monatomic ideal gas at a pressure...
Five moles of monatomic ideal gas have initial pressure 2.50 × 103 Pa and initial volume 2.10 m3. While undergoing an adiabatic expansion, the gas does 1530 J of work. Part A What is the final pressure of the gas after the expansion? Units: kPa Units: kPa
Five moles of monatomic ideal gas have initial pressure 2.50 × 103 Pa and initial volume 2.10 m3. While undergoing an adiabatic expansion, the gas does 1780 J of work. What is the final pressure of the gas after the expansion? (kPa)
With the pressure held constant at 230 kPa, 44 mol of a monatomic ideal gas expands from an initial volume of 0.80 m3 to a final volume of 1.9 m3. Review PartA With the pressure held constant at 230 kPa, 44 mol of a monatomic ideal gas expands from an initial volume of 0.80 m3 to a final volume of 1.9 m3 How much work was done by the gas during the expansion? Express your answer using two significant figures....
A monatomic ideal gas is held in a thermally insulated container with a volume of 0.0950 m3. The pressure of the gas is 111 kPa, and its temperature is 315 K. To what volume must the gas be compressed to increase its pressure to 150 kPa? At what volume will the gas have a temperature of 300 K?
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?
A monatomic ideal gas undergoes isothermal expansion from 0.08 m3 to 0.22 m3 at a constant temperature (initial pressure is 310 kPa). What are its (a) internal energy change (ΔEΔE), (b) net heat transfer (Q), and (c) net work done (W)? Use negative quantity for heat transfer out of the system or work done on the system.