Thermodynamics

Q 1.

From thermodynamic point of view, to which system the animals and plants belong?

Q 2.

Consider the following reaction between zinc and oxygen and choose the correct options out of the options given below:
2Zn(s) + 0₂(g) → 2ZnO(s); ∆H=-693.8 kJ mol^-1
(i) The enthalpy of two moles ZnO is less than the total enthalpy of two moles of Zn and one mole of oxygen by 693.8 kJ.
(ii) The enthalpy of two moles of ZnO is more than the total enthalpy of two moles of Zn and one mole of oxygen by 693.8 kJ.
(iii) 8 kJ mol ^-1 energy is evolved in the reaction.
(iv) 693.8 kJ mol^-1 energy is absorbed in the reaction.

Q 3.

Predict the sign of  âˆ†S for the following reaction  heat
CaCO₃ (s) ———> CaO(s) + CO₂(g)

Q 4.

Give reason for the following:
(a)Neither q nor w is a state function but q + w is a state function.
(b)A real crystal has more entropy than an ideal crystal.

Q 5.

Q 6.

In an exothermic reaction, heat is evolved, and system loses heat to the surroundings. For such system
(a) q_P will be negative                                                              
(b) ∆_γHwill be negative
(c) q_p will be positive                                                                
(d) ∆_γHwill be positive.

Q 7.

The entropy change can be calculated by using the expression ∆S = q _rev / T.  When water freezes in a glass beaker, choose the correct statement amongst the following:

When water freezes in a glass beaker, choose the correct statement amongst the following:

(a) ∆S_(system) decreases but ∆S_{(surroundings)} remains the same.
(b) ∆S_(system) increases but ∆S_{(surroundings)} decreases.
(C) ∆S_(system) decreases but ∆S_{(surroundmgs)}  increases.
(d) ∆S_(system) decreases but ∆S_{(surroundings)} also decreases.

Q 8.

When is bond energy equal to bond dissociation energy ?

Q 9.

The enthalpy of atomisation for the reaction CH₄(g) → C(g) + 4H(g) is 1665 kJ mol^-1. What is the bond energy of C – H bond?

Q 10.

Define the following:
(i) First law of thermodynamics.
(ii) Standard enthalpy of formation.

Q 11.

Calculate the standard enthalpy of formation of CH₃OH. from the following data:
(i) CH₃OH(l) + 3/2 0₂ (g) ———-> CO₂ (g) + 2H₂0 (l); ∆_rH^– = – 726kj mol^-1
(ii) C(s) + 0₂(g) —————>C0₂ (g); ∆_cH^– = -393 kj mol^-1
(iii) H₂(g) + 1/20₂(g) —————->H₂0 (l); ∆_fH^– = -286 kj mol^-1

Q 12.

1 g of graphite is burnt in a bomb calorimeter in excess of oxygen at 298 K and 1 atmospheric pressure according to the equation C(graphite) + 0₂ (g) —> C0₂ (g) During the reaction, temperature rises from 298 K to 299 K. If the heat capacity of the bomb calorimeter is 20.7 kJ/K, what is the enthalpy change for the above reaction at 298 K and 1 atm?

Q 13.

Calculate the number of kj of heat necessary to raise the temperature of 60 g of aluminium from 35 °C to 55 °C. Molar heat capacity of Al is 24  J mol^-1 K^-1.

Q 14.

When two moles of C₂H₆(g) are burnt, 3129 kj of heat is liberated. Calculate the heat of formation of C₂H₆(g). ∆_fH for  C0₂(g) and  H₂0(l) are-393.5 and -286 kj mol^-1  respectively.

Q 15.

For the reaction; 2Cl(g) ———-> Cl₂(g); what will be the signs of ∆H and ∆S?

Q 16.

Q 17.

What is the enthalpy of formation of the most stable form of an element in its standard state?

Q 18.

What is the condition for spontaneity in terms of free energy change?

Q 19.

Many thermodynamically feasible reactions do not occur under ordinary conditions. Why?

Q 20.

In an adiabatic process, no transfer-of heat takes place between system and surroundings. Choose the correct option for free expansion of an ideal gas under adiabatic condition from the following.

Q 21.

The difference between C_p and C_v can be derived using the empirical relation H = U + pV. Calculate the difference between C_p and C_v for 10 moles of an ideal gas.

Q 22.

The net enthalpy change of a reaction is the amount of energy required to break all the bonds in reactant molecules minus amount of energy required to form all the bonds in the product molecules. What will be the enthalpy change for the following reaction?
H₂(g) + Br₂(g)→2HBr(g)
Given that bond energy of H₂, Br₂ and HBr is 4.35 kJ mol^-1,192 kJ mol^-1 and 368 kJ mol ^-1 respectively.

Q 23.

Q 24.

Which of the following is not correct?
(a) ∆G is zero for a reversible reaction.
(b) ∆G is positive for a spontaneous reaction
(c) ∆G is negative tor a spontaneous reaction
(d) ∆G is positive for a non-spontaneous reaction.

Q 25.

Thermodynamics mainly deals with
(a) interrelation of various forms of energy and their transformation front one from  to another.
(b) energy changes in the processes which depend only on initial and final states of the microscopic system containing a few molecules.
(c) how and at what rate these energy transformations are carried out.
(d) the system in equilibrium state or moving from one equilibrium state to another equilibrium state.

Q 26.

A sample of 1.0 mol of a monoatomic ideal gas is taken through a cyclic process of expansion and compression as shown in the figure. What will be the value of ΔHfor the cycle as a whole?

Q 27.

The bond enthalpy of H2(g) is 436  kj mol^-1and that of N2 (g) is 941.3  kj mol^-1. Calculate the average bond enthalpy of an N-H bond in ammonia. Given: ∆H^– (NH₃) = -46 kj mol^-1

Q 28.

Heat capacity (C_P) is an extensive property but specific heat (c) is an intensive property. What will be the relation between C_p and c for 1 mol of water?

Q 29.

What do you mean by entropy?

Q 30.

Q 31.

Q 32.

Enthalpy of sublimation of a substance is equal to
(a) enthalpy of fusion + enthalpy of vapourisation
(b) enthalpy of fusion
(c) enthalpy of vapourisation
(d) twice the enthalpy of vapourisation.

Q 33.

Heat has randomising influence on a system and temperature is the measure of average chaotic motion of particles in the system. Write the mathematical relation which relates these three parameters.

Q 34.

Increase in enthalpy of the surroundings is equal to decrease in enthalpy of the system. Will the temperature of system and surroundings be the same when they are in thermal equilibrium?

Q 35.

Although heat is a path function but heat absorbed by the system under certain specific conditions is independent of path. What are those conditions? Explain.

Q 36.

Calculate the enthalpy change on freezing of 1.0 mol of water at 10.0 °C to ice at – 10.0 °C. A, H = 6.03 KJ mot1 at 0 °C. Cp [H20(l)J = 75.3  J mol^-1 K^-1; Cp [H20(s)J = 36.8  J mol^-1 K^-1.

Q 37.

At what temperature entropy of a substance is zero?

Q 38.

What is an adiabatic process?

Q 39.

What is free energy in terms of thermodynamics?

Q 40.

Define extensive properties.

Q 41.

How are internal energy change, free energy change and entropy change are related to one another?

Q 42.

Define intensive properties.

Q 43.

What are the units of entropy?

Q 44.

Q 45.

Why standard entropy of an elementary substance is not zero whereas standard enthalpy of formation is taken as zero?

Q 46.

During complete combustion of one mole of butane, 2658 kJ of heat is released. The thermochemical reaction for above change is

Q 47.

For an ideal gas. the work of reversible expansion under isothermal condition 1.0 mol of an ideal gas is expanded isothermally and reversibly to ten times of its original volume, in two separate experiments. The expansion is carried out at 300 K and at 600 K respectively. Choose the correct option.
can be calculated by using expression w = -nRT In V_f / V_i A sample containing
(a) Work done at 600 K is 20 times the work done at 300 K.
(b) Work done at 300 K is twice the work done at 600 K
(c) Work done at 600 K is twice the work done at 300 K.
(d) ∆U= 0 in both cases.

Q 48.

18.0 g of water completely vapourises at 100 °C and 1 bar pressure and the enthalpy change in the process is
40.79 kJ mol^-1. What will be the enthalpy change for vapourising two moles of water under the same conditions? What is the standard enthalpy of vapourisation for water?

Q 49.

At 298 K, K_p for the reaction N₂0₄(g)⇌ 2N0₂(g) is 0.98. Predict whether the reaction is spontaneous or not.

Q 50.

Identify the state functions and path functions out of the following: enthalpy, entropy, heat, temperature, work, free energy.