All of these options(A,B,C,D) are correct

When a directly measured enthalpy change of reaction is not available

To calculate an enthalpy change value through multiple steps

Because enthalpy is a State Function

As an easy way to calculate the enthalpy change of a reaction

MCQ Questions for Class 11 Medical Chemistry Thermodynamics Quiz 3

For the change, $$C_{diamond}\longrightarrow +C_{graphite}; \:\Delta H=-1.89 \:kJ$$, if 6 g of diamond and 6 g of graphite are separately burnt to yield $$CO_2$$ the heat liberated in first case is:

0%
less than in the second case by 1.89 kJ
0%
less than in the second case by 11.34 kJ
0%
less than in the second case by 14.34 kJ
0%
more than in the second case by 0.945 kJ

The relationship between the free energy change $$(\Delta G)$$ and entropy change $$(\Delta S)$$ at constant temperature $$(T)$$ is

0%
$$\,\Delta G = \Delta H + T\Delta S$$
0%
$$\,\Delta H = \Delta G + T\Delta S$$
0%
$$\,T\Delta S = \Delta G + \Delta H$$
0%
$$\,\Delta G = -\Delta H - T\Delta S$$

Hess law is applicable for determination of enthalpy of

0%
Reaction
0%
Formation
0%
Transition
0%
All of above

A change in the free energy of a system at constant temperature and pressure will be:

$$\Delta_{ sys }G = \Delta_{ sys }H - T\Delta_{ sys }S$$

At constant temperature and pressure

$$\Delta_{ sys }G < 0 (spontaneous)$$
$$\Delta_{ sys }G = 0 (equilibrium)$$
$$\Delta_{ sys }G > 0 (non-spontaneous)$$

The free energy for a reaction having $$\Delta H = 31400 cal$$, $$\Delta S = 32 cal K^{ -1 } mol^{ -1 }$$ at $$1000^{ \circ }C$$ is?

0%
$$-9336 cal$$
0%
$$-7006 cal$$
0%
$$-2936 cal$$
0%
$$+9006 cal$$

The heat of hydrogenation of ethene is $$x_1$$ and that of benzene is $$x_2$$
Hence resonance energy of benzene is

0%
$$x_1 - x_2$$
0%
$$x_1 + x_2$$
0%
$$3x_1 - x_2$$
0%
$$x_1 - 3x_2$$

$$C(diamond) + 2H_2(g)\longrightarrow CH_4(g);\,\,\Delta H_1$$

$$C(g) + 4H(g)\longrightarrow CH_4(g);\,\,\Delta H_2$$

Select the correct relation.

0%
$$\Delta H_1 = \Delta H_2$$
0%
$$\Delta H_1 > \Delta H_2$$
0%
$$\Delta H_1 < \Delta H_2$$
0%
$$\Delta H_1 = \Delta H_2 + \Delta_{ vap }H(C) + \displaystyle \Delta_{ diss }H(H_2)$$

Which one of the following correctly represents the physical significance of Gibb's energy change?

0%
$$\displaystyle -\Delta G={ W }_{ \text{compression} }$$
0%
$$\displaystyle \Delta G={ W }_{ \text{expansion} }$$
0%
$$\displaystyle \Delta G={ -W }_{ \text{expansion} }={ W }_{ \text{non-expansion} }$$
0%
$$\displaystyle -\Delta G={ W }_{ \text{expansion} }$$

The Born Haber cycle below represents the energy changes occurring at 298K when KH is formed from its elements
v : $${ \Delta H }_{ atomisation }$$ K = 90 kJ/mol
w : $${ \Delta H }_{ ionisation }$$ K = 418 kJ/mol
x : $${ \Delta H }_{ dissociation }$$ H = 436 kJ/mol
y : $${ \Delta H }_{ electron affinity }$$ H = 78 kJ/mol
z : $${ \Delta H }_{ lattice }$$ KH = 710 kJ/mol

In terms of the letters v to z the expression for
$${ \Delta H }_{ i }$$ of K is $${ \Delta H }_{ i }$$ = $$w/2$$.
If true enter 1, else enter 0.

0%
0
0%
1
0%
2
0%
3

$$H_2(g) + Br_2(g)\longrightarrow 2HBr(g); \Delta H^{ \ominus } = -72.40 kJ$$
$$\Delta G^{ \ominus } = -106.49 kJ, T = 298 K$$
The value $$\Delta S$$ is .

0%
$$114.3 J k^{ -1 }$$
0%
$$-114.3 J k^{ -1 }$$
0%
$$1363.6 J k^{ -1 }$$
0%
Noe of these

Based on the first law of thermodynamics, which one of the following is correct ?

0%
$$\text{For an isochoric process, E = -Q}$$
0%
$$\text{For an adiabatic process, E = -Q}$$
0%
$$\text{For an isothermal process, E = -Q}$$
0%
$$\text{For an cyclic process, W = -Q}$$

A bomb calorimeter is used to measure the value of heat of reaction at a constant

0%
Volume
0%
Pressure
0%
Temperature
0%
None of these

All spontaneous process proceed in one direction only.

0%
True
0%
False

$$H_2(g) + \frac{ 1 }{ 2 }O_2(g)\longrightarrow 2H_2O(l); \Delta H = -286 kJ$$
$$2H_2(g) + O_2(g)\longrightarrow 2H_2O(l)......... kJ(\pm?)$$

0%
$$2H_2(g) + O_2(g)\longrightarrow 2H_2O(l) + 572 kJ$$.
0%
$$2H_2(g) + O_2(g)\longrightarrow 2H_2O(l) - 572 kJ$$.
0%
$$2H_2(g) + O_2(g)\longrightarrow 2H_2O(l) +0 kJ$$.
0%
None of these

In terms of the letters v to z the expression for
$${ \Delta H }_{ electron affinity }$$ of H is $${ \Delta H }_{ electron affinity }$$ is __.
I

0%
$$y$$
0%
$$y/2$$
0%
$$2y$$
0%
$$y/3$$

The heat released when the requisite amount of ions in the gaseous state combine to give 1 mol of crystal lattice is known as:

0%
lattice energy
0%
hydration energy
0%
formation energy
0%
none of the above

The enthalpy change for reaction (i) is:

0%
+ 100.23 kJ/mol
0%
+ 127.5 kJ/mol
0%
- 127.5 kJ/mol
0%
- 100.23 kJ/mol

Gibbs- Helmholtz equation is

0%
$$\Delta G = \Delta H - T\Delta S$$.
0%
$$\Delta G = \Delta H +T\Delta S$$.
0%
$$\Delta G = T\Delta H - \Delta S$$.
0%
none of these

What can be concluded about the values of $$\Delta H$$ and $$\Delta S$$ from this graph ?

0%
$$\Delta H >0, \:\Delta S >0$$
0%
$$\Delta H >0, \:\Delta S <0$$
0%
$$\Delta H <0, \:\Delta S >0$$
0%
$$\Delta H <0, \:\Delta S <0$$

State True or False.

Gibbs- Helmholtz equation is $$\Delta G = T\Delta H - \Delta S$$.

0%
True
0%
False

The Born Haber cycle below represents the energy changes occurring at 298K when $$KH$$ is formed from its elements
v : $${ \Delta H }_{ atomisation }$$ $$K = 90 kJ/mol$$
w : $${ \Delta H }_{ ionisation }$$ $$K = 418 kJ/mol$$
x : $${ \Delta H }_{ dissociation }$$ $$H = 436 kJ/mol$$
y : $${ \Delta H }_{ electron affinity }$$ $$H = 78 kJ/mol$$
z : $${ \Delta H }_{ lattice }$$ $$KH = 710 kJ/mol$$

Calculate the value of $$\Delta $$$$H$$ showing all your working.

0%
124 kJ/mol
0%
-124 kJ/mol
0%
124 J/mol
0%
None of these

$$2$$ moles of $$CO$$ and $$1$$ mole of $$O_{2}$$ are taken in a container of volume $$1$$ litre to form $$2$$ moles of $$CO_{2}$$ according to equation

$$2CO + O_{2}\rightarrow 2CO_{2}, \ \Delta H = -560KJ$$.

In this process, pressure changes from $$70\ atm$$ to $$40\ atm$$. Find out value of $$\Delta U$$ at $$500\ K$$.

[Given: gases deviates apprecially from ideal nature. $$1\ atm-litre = 0.1\ KJ$$].

0%
$$-530\ KJ$$
0%
$$-500\ KJ$$
0%
$$-557\ KJ$$
0%
$$-560\ KJ$$

On complete reaction with water, $$0.1 g$$ of $$KH$$ gave a solution requiring 25 $${ cm }^{ 3 }$$ of 0.1M $$HCl$$ for neutralisation.Calculate the relative atomic mass of potassium from this information.

0%
$$39$$
0%
$$40$$
0%
$$41$$
0%
None of these

Write a balanced equation for the reaction of $$KH$$ with water.

0%
$$KH + H_2O \rightarrow KOH + H_2O_2$$
0%
$$KH + H_2O \rightarrow KOH + H_2$$
0%
$$KH + H_2O \rightarrow K(OH)_2 + H_2$$
0%
$$KH + H_2O \rightarrow KOH + H_2O$$

The amount of heat required to raise the temperature of a substance through 1$$^o$$C is called

0%
thermal energy
0%
calories
0%
heat capacity
0%
specific heat capacity

Hess's law is used to calculate

0%
Enthalpy of reaction
0%
Entropy of reaction
0%
Work done in reaction
0%
All of these

Which of the following type of energies are involved in Born Haber`s cycle ?

0%
a. $$\Delta_{ sub }H$$
0%
b. ionisation energy
0%
c. bond dissociation energy
0%
d. lattice energy

Specific heat capacity of lead is $$120\space J\space kg^{-1}\space K^{-1}$$. When $$7200J$$ of heat is supplied to $$5kg$$ of lead, the rise in temperature is

0%
$$8^{\small\circ}C$$
0%
$$10^{\small\circ}C$$
0%
$$12^{\small\circ}C$$
0%
$$14^{\small\circ}C$$

Gibbs- Helmholtz equation is:

0%
$$\Delta G = T\Delta H + \Delta S$$
0%
$$\Delta G = - T\Delta H - \Delta S$$
0%
$$\Delta G = T\Delta H - \Delta S$$
0%
$$\Delta G = -T\Delta H + \Delta S$$

A hypothetical reaction $$A \rightarrow 2B$$, proceeds through following sequence of steps:
(i) $$A \rightarrow C; \Delta H = q$$
(ii) $$C \rightarrow D; \Delta H = v$$
(iii) $$\dfrac{1}{2}D \rightarrow B; \Delta H = x$$
Then the heat of reaction is:

0%
$$q - v + 2x$$
0%
$$q + v - 2x$$
0%
$$q + v + 2x$$
0%
$$q + 2v - 2x$$

For the reaction, $$X_2Y_4(l) \longrightarrow 2XY_2(g)$$ at 300 K, the values of $$\Delta U$$ and $$\Delta S$$ are 2 kcal and 20 cal $$K^{-1}$$ respectively. The value of $$\Delta G$$ for the reaction is

0%
- 3400 cal
0%
3400 cal
0%
- 2800 cal
0%
2000 cal

What wiII be the heat of formation of methane, if the heat of combustion of carbon is $$'-x' kJ$$, heat of formation of water is $$'-y' kJ$$ and heat of combustion of methane is $$'z' kJ$$?

0%
$$(-x - y + z) kJ$$
0%
$$(-z -x + 2y) kJ$$
0%
$$(-x - 2y - z) kJ$$
0%
$$(-x -2y + z) kJ$$

For the reaction of one mole of zinc dust with one mole of sulphuric acid in a bomb calorimeter, $$\triangle U$$ and $$w$$ corresponds to:

0%
$$\triangle U < 0, w = 0$$
0%
$$\triangle U < 0, w < 0$$
0%
$$\triangle U > 0, w = 0$$
0%
$$\triangle U > 0, w > 0$$

Mark the point where the temperature of $$H_2O$$ is changing at $$4.18 J/g^o$$C(or $$1$$ $$cal/g^oC$$)?

0%
A
0%
B
0%
C
0%
D
0%
E

From the following information given, determine $$\Delta H^o$$ for the decomposition of sodium chlorate?
$$NaClO_3(s)\rightarrow NaCl(s)+\displaystyle\frac{3}{2}O_2(g)$$
$$(\Delta H^o_f$$ values $$:$$ $$NaClO_3(s)=358J/mol,$$ $$NaCl(s)=-410j/mol$$, $$O_2(g)=0$$ $$kcal/mol)$$

0%
$$52.0$$J
0%
$$-52.0$$J
0%
$$768$$J
0%
$$-768$$J
0%
$$\displaystyle\frac{3}{2}(-768J)$$

According to Hess's law, the heat of reaction depends upon

0%
initial condition of reactants
0%
initial and final conditions of reactants
0%
intermediate path of the reaction
0%
end conditions of reactants

If $$C+{O}_{2}.\longrightarrow {CO}_{2}+94.2kcal$$
$${H}_{2}+\cfrac{1}{2}{O}_{2}\longrightarrow {H}_{2}+68.3kcal$$
$${CH}_{4}+2{O}_{2}\longrightarrow {CO}_{2}+2{H}_{2}O+210.8kcal$$
Then, the heat of formation of methane will be

0%
$$47.3kcal$$
0%
$$20.0kcal$$
0%
$$45.9kcal$$
0%
$$-47.3kcal$$

What is the characteristic of a material which undergo spontaneous combustion?

0%
High calorific value
0%
High vapour pressure
0%
Low ignition temperature
0%
All of the above

Statement 1 : Candles can be safely stored at room temperature, even though their reaction with air is spontaneous at room temperature.
Statement 2 : The reaction that takes place when a candle is burned involves a decrease in entropy.

0%

Both Statement 1 and Statement 2 are correct and Statement 2 is the correct explanation of Statement 1.
0%

Both Statement 1 and Statement 2 are correct and Statement 2 is not the correct explanation of Statement 1.
0%

Statement 1 is correct but Statement 2 is not correct.
0%

Statement 1 is not correct but Statement 2 is correct.
0%

Both the Statement 1 and Statement 2 are not correct.

Which statement is correct about heat?

0%
It is a measure of the transfer of energy due a temperature difference
0%
The heat transfer is always from hot to cold
0%
The heat absorbed by the surroundings equals the heat released by the system
0%
The amount of heat lost or gained during a reaction is directly related to the enthalpy change of the reaction.
0%
All answers are correct

Hess's Law is used

0%
When a directly measured enthalpy change of reaction is not available
0%
To calculate an enthalpy change value through multiple steps
0%
Because enthalpy is a State Function
0%
As an easy way to calculate the enthalpy change of a reaction
0%
All of these options(A,B,C,D) are correct

If 100.0 J of energy is added to 50.0 g of Cu, initially at $$25.0^o C$$, what will be the final temperature? (Specific heat capacity = 0.382 J/ C.g )

0%
$$31.2^o C$$
0%
$$30.24^o C$$
0%
$$25.2^o C$$
0%
$$25.19^o C$$
0%
$$19.8^o C$$

10 g of liquid at 300K is heated to 350 K. The liquid absorbs 6 kcals. What is the specific heat of the liquid (in $$cal/ \displaystyle { g }^{ \circ }C$$)?

0%
6
0%
12
0%
60
0%
120

A spontaneous reaction occurs:

0%
by itself and quickly
0%
with outside intervention and quickly
0%
by itself and slowly
0%
with outside intervention and slowly
0%
by itself but it has now effect on how fast the reaction takes

$$10\ g$$ of liquid at $$300\ K$$ are heated to $$350\ K$$. The liquid absorbs $$6\ kcal$$. What is the specific heat of the liquid (in $$cal/g^{\circ}C)$$?

0%
$$6$$
0%
$$12$$
0%
$$60$$
0%
$$120$$
0%
$$600$$

Which set of the conditions given below guarantees that a reaction will be spontaneous?

0%
$$\Delta H(+)$$ and $$\Delta S(-)$$
0%
$$\Delta H(-)$$ and $$\Delta S(+)$$
0%
$$\Delta H(+)$$ and $$\Delta S(+)$$ at low temperature
0%
$$\Delta H(-)$$ and $$\Delta S(-)$$ at high temperature
0%
$$\Delta G(+)$$

Heat required, to rise one unit mass of a substance by 1 degree Celsius, is known as ......................... .

0%
gibbs free energy
0%
heat of formation
0%
specific heat
0%
Heinsenberg uncertainty principle
0%
heat of vaporization

Determine the heat of reaction for the combustion of sulphur dioxide:

$$\displaystyle 2{ SO }_{ 2 }\left( g \right) +{ O }_{ 2 }\left( g \right) \rightarrow 2{ SO }_{ 3 }\left( g \right) $$

Given the following thermochemical equations:

I. $$\displaystyle { S }_{ 8 }\left( s \right) +8{ O }_{ 2 }\left( g \right) \rightarrow 8{ SO }_{ 2 }\left( g \right) \Delta H=-2374.6kJ$$
II. $$\displaystyle { S }_{ 8 }\left( s \right) +12{ O }_{ 2 }\left( g \right) \rightarrow 8{ SO }_{ 3 }\left( g \right) \Delta H=-3165.8kJ$$

0%
-5540.4 kJ
0%
-1385.1 kJ
0%
-791.2 kJ
0%
-197.8 kJ
0%
-700 kJ

When one mole of sulfur burns to form $$SO_2$$, 1,300 calories are released. When one mole of sulfur burns to form $$SO_3$$, 3,600 calories are released. What is the $$\Delta H$$ when one mole of $$SO_2$$ is burned to form $$SO_3$$?

0%
3,900 cal
0%
-1,950 cal
0%
1,000 cal
0%
-500 cal
0%
-2, 300 cal

$$\displaystyle S\left( s \right) +{ O }_{ 2 }\left( g \right) \rightarrow { SO }_{ 2 }\left( g \right) \quad \Delta { H }^{ \circ }=-297kJ$$
$$\displaystyle 2{ SO }_{ 2 }\left( g \right) +{ O }_{ 2 }\left( g \right) \rightarrow 2{ SO }_{ 3 }\left( g \right) \quad \Delta { H }^{ \circ }=-198kJ$$
Given the above thermochemical reactions, what is the heat of reaction for the formation of $$\displaystyle { SO }_{ 3 }\left( g \right) $$ provided below?
$$\displaystyle S\left( s \right) +{ 3/2O }_{ 2 }\left( g \right) \rightarrow { SO }_{ 3 }\left( g \right) $$

0%
-495 kJ
0%
-396 kJ
0%
-198 kJ
0%
+99
0%
+198 kJ

Statement I
As ice absorbs heat and begins to melt, its temperature remains constant
Because
Statement II
Changes of state bring about changes in a substances potential energy, not in its kinetic energy

0%
Statement 1 and Statement 2 are correct and Statement 2 is the correct explanation of Statement 1
0%
Both the Statement 1 and Statement 2 are correct and Statement 2 is not the correct explanation of Statement 1.
0%
Statement 1 is correct but Statement 2 is not correct.
0%
Statement 1 is not correct but Statement 2 is correct.
0%
Both the Statement 1 and Statement 2 are not correct.

CBSE Questions for Class 11 Medical Chemistry Thermodynamics Quiz 3 - MCQExams.com

Born-Haber Cycle

0:0:1

Practice Class 11 Medical Chemistry Quiz Questions and Answers

CBSE Questions for Class 11 Medical Chemistry Thermodynamics Quiz 3 - MCQExams.com

Born-Haber Cycle

0:0:1

Practice Class 11 Medical Chemistry Quiz Questions and Answers

Support mcqexams.com by disabling your adblocker.