The bond dissociation energies of and XY are in the ratio of 1 : 0.5 : 1. ∆H for the formation of XY is –200 kJ mol–1. The bond dissociation energy of X2 will be
1. 200 kJ mol–1
2. 100 kJ mol–1
3. 800 kJ mol–1
4. 400 kJ mol–1
For a given reaction, if ΔH = 35.5 kJ/mol and ΔS = 83.6 J/K·mol,
at what temperature is the reaction spontaneous?
(Assume ΔH and ΔS remain constant with temperature.)
1. | T < 425 K | 2. | T > 425 K |
3. | All temperatures | 4. | T > 298 K |
A gas is allowed to expand in a well insulated container against a constant external pressure of 2.5 atm from an initial volume of 2.50 L to a final volume of 4.50 L. The change in internal energy U of the gas in joules will be
(1) 1136.25 J
(2) - 500 J
(3) - 505 J
(4) + 515 J
For a given reaction, ∆H = 35.5 kJ mol–1 and ∆S = 83.6 J K–1 mol–1. The reaction is spontaneous at:
(Assume that ∆H and ∆S do not vary with temperature)
1. | T > 425K | 2. | All temperatures |
3. | T > 298K | 4. | T < 425K |
A gas is allowed to expand in a well-insulated container against a constant external pressure of 2.5atm from an initial volume of 2.50 L to a final volume of 4.50L. The change in internal energy U of the gas in joules will be:
1. –500J
2. –505J
3. –506J
4. –508J
The correct thermodynamic conditions for the spontaneous reaction at all temperatures is
For a sample of a perfect gas when its pressure is changed isothermally from Pi to Pf, the entropy change is given by:
1.
2.
3.
4.