Calculate the work done during compression of 2 mol of an ideal gas from a volume of 1 m3 to 10 dm3 300K against a pressure of 100 KPa
-99 kJ
+99 kJ
+22.98 kJ
-22.98 kJ
A gas will approach ideal behavior at
Low temperature and low pressure
Low temperature and high pressure
High temperature and low pressure
High temperature and high pressure
Mixing of N2 and H2 from an ideal gas mixture at room temperature in a container. For this process, which of the following statement is true?
Consider a fuel cell supplied with 1 mol of H2 gas and 10 moles of O2 gas. If fuel cell is operated at 9.63 mA current, how long will it deliver power? (Assume 1 F = 96500 C/mole of electrons).
1 × 106 s
0.5 × 106 s
2 × 106 s
4 × 106 s
Critical density of a gas having molecular weight 39 g mol-1 is 0.1 × 103 g cm-3. Its critical volume in L mol-1 is
0.390
3.90
0.039
39.0
18 g of glucose is dissolved in 178.2 g of water. The vapour pressure of the solution at 100° C is (vapour pressure of pure water at 100° C is 760 mm Hg)
767.6 mm Hg
760 mm Hg
752.4 mm Hg
725.4 mm Hg
If two moles of an ideal gas at 500 K occupies a volume of 41 L, the pressure of the gas is (R = 0.082 L atm K-1 mol-1)
2 atm
3 atm
4 atm
5 atm
At 273 K, the density of a certain gaseous oxide at 2 atm is same as that of dioxygen at 5 atm. The molecular mass of the oxide (in g mol-1) is
80
64
32
160
A.
80
We know that,
pV = nRT =
pM = RT
pM = dRT
or, d =
Since, R and T are constant and d1 = d2
p1M1 = p2M2
2 × M1 = 5 × 32
M1 = = 80g mol-1