Suppose 1.50 m^3 of a gas with = 1.40, initially at 300 K and 1.0 atm,...
3) Suppose a di-atomic gas, initially at 300.00 K and 2.00 atm, is reduced adiabatically to one quarter of its initial volume. a) Find its final pressure Final rempreature Volume(m2) tob oniono ad b) If it was a mono-atomic gas, would the final pressure be larger or smaller than part a)? Explain c) If there are 5.00 mol of the gas, what is the final volume? (1.00 atm 101.3 kPa) Heebl oimelsonem to lom-a aowdns ls bni worle ploy o-die...
A 1.60-mol sample of helium gas initially at 300 K, and 0.400 atm is compressed isothermally to 1.40 atm. Note that the helium behaves as an ideal gas. (a) Find the final volume of the gas. (b) Find the work done on the gas. (c) Find the energy transferred by heat.
An ideal gas, initially at a pressure of 9.1 atm and a temperature of 311 K, is allowed to expand adiabatically until its volume doubles.What is the gas’s final pressure, in atmospheres, if the gas is diatomic?
1) What is the final pressure (expressed in atm) of a 3.05 L system initially at 724 mm Hg and 298 K that is compressed to a final volume of 2.51 L at 273 K? 1) 2) What is the pressure of a 1.0 L flask containing 0.60% of He at 25°C? (R-0.0821 L atm/mol K) 3) What is the volume of 28.0 g of nitrogen gas at STP? 3) 4) What is the final pressure of a system (atm)...
A 2.60-mol sample of helium gas initially at 300 K, and 0.400 atm is compressed isothermally to 1.00 atm. Note that the helium behaves as an ideal gas. (a) Find the final volume of the gas. (b) Find the work done on the gas. (c) Find the energy transferred by heat.
The ideal gas initially at 500 K and 1 atm was compressed adiabatically under two conditions to 5 atm pressure. The final temperature (Ti) under reversible condition and the final temperature (T2) under irreversible condition are related by: O Ti > T2 O T = T2 OT <T2
A 2.60-mol sample of helium gas initially at 300 K, and 0.400 atm is compressed isothermally to 1.00 atm. Note that the helium behaves as an ideal gas. (a) Find the final volume of the gas.? m3 (b) Find the work done on the gas. kJ (c) Find the energy transferred by heat. kJ
An ideal gas with γ=1.4 occupies 5.0 L at 300 K and 100 kPa pressure and is heated at constant volume until its pressure has doubled. It's then compressed adiabatically until its volume is one-fourth its original value, then cooled at constant volume to 300 K , and finally allowed to expand isothermally to its original state. Find the net work done on the gas in Joules.
Five moles of carbon dioxide (CO2), initially 3 atm and 300 K, is trapped inside a piston-cylinder assembly. It is then allowed to expand against atmospheric pressure adiabatically. The constant- pressure heat capacity of CO2 is given by the following equation: p = 5.4574 (1.045 × 10-3)(T/K)-(1.157 × 105)(T/K)-2 (a) If we assume that the expansion is infinitely slow and quasi-static, calculate the final temperature and total volume of the carbon dioxide gas when it reaches 1 atm. Also calculate...
1.50 moles of ideal gas is kept in a container at a pressure of 2.00 atm. At constant pressure, the gas is compressed to half its original volume. If temperature remains constant at 315 K (ΔE = 0), how much heat leaves the system?