Enthalpy change for the reaction,
4H(g) 2H2(g) is -869.6 kJ
The dissociation energy of H-H bond is
1. -869.6 kJ
2. + 434.8 kJ
3. +217.4 kJ
4. -434.8 kJ
Given the following bond energies:
H-H bond energy | 431.37 kJ mol-1 |
C=C bond energy | 606.10 kJ mol-1 |
C-C bond energy | 336.49 kJ mol-1 |
C-H bond energy | 410.50 kJ mol-1 |
Based on the data given above, enthalpy change for the following reaction will be:
1. 1523.6 kJ mol-1
2. -243.6 kJ mol-1
3. -120.0 kJ mol-1
4. 553.0 kJ mol-1
The values of H and S for the given reaction are 170 kJ and 170 JK–1, respectively.
\(\mathrm{C} \text { (graphite) }+\mathrm{CO}_2(\mathrm{~g}) \rightarrow 2 \mathrm{CO}(\mathrm{g})\)
This reaction will be spontaneous at:
1. 710 K
2. 910 K
3. 1110 K
4. 510 K
Which of the following are not state functions?
(I) q + W (II) q
(III) W (IV) H-TS
1. (I) and (IV)
2. (II), (III) and (IV)
3. (I) , (II) and (III)
4. (II) and (III)
Consider the following reactions :
(i)
(ii)
(iii)
(iv)
Enthalpy of formation of H2O(l) is:
1. -x2 kJ mol-1
2. +x3 kJ mol-1
3. -x4 kJ mol-1
4. -x1 kJ mol-1
Identify the correct statement for change of Gibbs energy for a system (Gsystem) at constant temperature and pressure:
(1) If Gsystem > 0, the process is spontaneous
(2) If Gsystem = 0, the system has attained equilibrium
(3) If Gsystem = 0, the system is still moving in a particular direction
(4) If Gsystem < 0, the process is not spontaneous
The enthalpy and entropy change for the reaction :
Br2 (l) + Cl2 (g) 2BrCl (g)
are 30 kJ mol-1 and 105 J K-1 mol-1 respectively.
The temperature at which the reaction will be in equilibrium is :
1. | 285.7 K | 2. | 273.4 K |
3. | 450.9 K | 4. | 300.1 K |
The enthalpy of combustion of H2, cyclohexene (C6H10) and cyclohexane (C6H12) are -241, -3800 and -3920 kJ per mol respectively. Heat of hydrogenation of cyclohexene is:
(a) -121 kJ per mol
(b) +121 kJ per mol
(c) +242 kJ per mol
(d) -242 kJ per mol
Consider the reactionat 300K
H2(9) + Cl2(9) →2HCI(g), ΔH° = — 185 KJ
If 3 mole of H2 completely react with 3 mol of Cl2 to form Cl, U° of the reaction will be
(1) Zero
(2) –185 KJ
(3) -555 KJ
(4) None
For a perfectly crystalline solid Cpm = aT3, where a is constant. If Cpm is 0.42 J/K–mol at 10 K, molar entropy at 10 K is
1. 0.42 J/K–mol
2. 0.14 J/K–mol
3. 4.2 J/K–mol
4. zero