Electrochemistry MCQ Questions & Answers in Physical Chemistry | Chemistry
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201.
The $$EMF$$ of the cell $$\left. {Tl/T{l^ + }\left( {0.001\,M} \right)} \right|$$ $$\left| {C{u^{2 + }}\left( {0.01\,M} \right)/Cu} \right.$$ is $$0.83.$$ The cell $$EMF$$ can be increased by
A
Increasing the concentration of $$T{l^ + }\,ions.$$
B
Increasing the concentration of $$C{u^{2 + }}\,ions.$$
C
Increasing the concentration of $$T{l^ + }$$ and $$C{u^{2 + }}\,ions.$$
D
None of these
Answer :
Increasing the concentration of $$C{u^{2 + }}\,ions.$$
The oxidation potential
$$ \propto \frac{1}{{{\text{Concentration of ions}}}}$$ and reduction potential $$ \propto $$ concentration of $$ions.$$ The cell voltage can be increased by decreasing the concentration of ions around anode or by increasing the concentration of ions around cathode
202.
The most convenient method to protect the bottom of the ship made of iron is
A
coating it with red lead oxide
B
white tin plating
C
connecting it with $$Mg$$ block
D
connecting it with $$Pb$$ block
Answer :
white tin plating
The most convenient method to protect the bottom of ship made of iron is white tin plating which prevents the build up of barnacles.
203.
A variable, opposite external potential $$\left( {{E_{ext}}} \right)$$ is applied to the cell $$Zn\left| {Z{n^{2 + }}\left( {1\,M} \right)} \right|\left| {C{u^{2 + }}\left( {1\,M} \right)} \right|Cu,$$ of potential $$1.1\,V.$$ When $${E_{ext}} < 1.1\,V$$ and $${E_{ext}} > 1.1\,V,$$ respectively electrons flow from :
A
anode to cathode in both cases
B
cathode to anode and anode to cathode
C
anode to cathode and cathode to anode
D
cathode to anode in both cases
Answer :
anode to cathode and cathode to anode
$$EMF$$ of galvanic cell $$ = 1.1\,volt$$
If $${E_{ext}} < EMF$$ then electron flows steadily from anode to cathode while If $${E_{ext}} > EMF$$ then electron flows from cathode to anode as polarity is changed.
204.
Given below are the standard electrode potentials of few half-cells. The correct order of these metals in increasing reducing power will be $$\frac{{{K^ + }}}{K} = - 2.93\,V,\frac{{A{g^ + }}}{{Ag}} = 0.80\,V,$$ $$\frac{{M{g^{2 + }}}}{{Mg}} = - 2.37\,V,\frac{{C{r^{3 + }}}}{{Cr}} = - 0.74\,V.$$
A
$$K < Mg < Cr < Ag$$
B
$$Ag < Cr < Mg < K$$
C
$$Mg < K < Cr < Ag$$
D
$$Cr < Ag < Mg < K$$
Answer :
$$Ag < Cr < Mg < K$$
Lower the reduction potential greater is the reducing power. Hence, increasing order of reducing power is $$Ag < Cr < Mg < K$$
205.
A solution contains $$F{e^{2 + }},F{e^{3 + }}$$ and $${I^ - }\,ions.$$ This solution was treated with iodine at $${35^ \circ }C.\,\,{E^ \circ }$$ for $$\frac{{F{e^{3 + }}}}{{F{e^{2 + }}}}$$ is $$ + 0.77\,V$$ and $${E^ \circ }$$ for $$\frac{{{I_2}}}{{2{I^ - }}} = 0.536\,V.$$ The favourable redox reaction is :
A
$${I_2}$$ will be reduced to $${I^ - }$$
B
There will be no redox reaction
C
$${I^ - }$$ will be oxidised to $${I_2}$$
D
$$F{e^{2 + }}$$ will be oxidised to $$F{e^{3 + }}$$
Answer :
$${I^ - }$$ will be oxidised to $${I_2}$$
206.
If $$54\,g$$ of silver is deposited during an electrolysis reaction, how much aluminium will be deposited by the same amount of electric current?
A
2.7 $$g$$
B
4.5 $$g$$
C
27 $$g$$
D
5.4 $$g$$
Answer :
4.5 $$g$$
$$1\,F$$ deposits $$108\,g$$ of $$Ag\left( {A{g^ + } + {e^ - } \to Ag} \right)$$
$$54\,g$$ of $$Ag$$ will be deposited by $$\frac{1}{{108}} \times 54 = \frac{1}{2}F$$
$$3\,F$$ deposit $$27\,g$$ of $$Al$$ $$\left( {A{l^{3 + }} + 3{e^ - } \to Al} \right)$$
$$\frac{1}{2}F$$ will deposit $$\frac{{27}}{3} \times \frac{1}{2} = 4.5\,g$$ of $$Al$$
207.
Mark the correct Nernst equation for the given cell. $$F{e_{\left( s \right)}}\left| {F{e^{2 + }}\left( {0.001\,M} \right)} \right|\left| {{H^ + }\left( {1\,M} \right)} \right|$$ $$\left. {{H_{2\left( g \right)}}\left( {1\,bar} \right)} \right|P{t_{\left( s \right)}}$$
208.
An acidic solution of $$C{u^{2 + }}$$ containing $$0.4\,g$$ of $$C{u^{2 + }}$$ ions is electrolysed until all the copper is deposited. What is the volume of oxygen evolved at $$NTP?$$
209.
Faraday’s laws of electrolysis are related to the
A
atomic number of the reactants.
B
atomic number of the anion.
C
equivalent weight of the electrolyte.
D
speed of the cation.
Answer :
equivalent weight of the electrolyte.
$$\frac{{{W_1}}}{{{W_2}}} = \frac{{{E_1}}}{{{E_2}}} = \frac{{{Z_1}\,{\text{it}}}}{{{Z_2}\,{\text{it}}}}\,\,\,\,\,\,\,\therefore \,\,\frac{{{Z_1}}}{{{Z_2}}} = \frac{{{E_1}}}{{{E_2}}}$$
Here$${E_1}$$ & $${E_2}$$ are equivalent weights of the ions.
210.
In a cell that utilises the reaction $$Zn\left( s \right) + 2{H^ + }\left( {aq} \right) \to Z{n^{2 + }}\left( {aq} \right) + {H_2}\left( g \right)$$ addition of $${H_2}S{O_4}$$ to cathode compartment, will
A
increase the $$E$$ and shift equilibrium to the right
B
lower the $$E$$ and shift equilibrium to the right
C
lower the $$E$$ and shift equlibrium to the left
D
increase the $$E$$ and shift equilibrium to the left
Answer :
increase the $$E$$ and shift equilibrium to the right
$$\eqalign{
& Zn\left( s \right) + 2{H^ + }\left( {aq} \right) \rightleftharpoons Z{n^{2 + }}\left( {aq} \right) + {H_2}\left( g \right) \cr
& {E_{cell}} = E_{cell}^ \circ - \frac{{0.059}}{2}\log \frac{{\left[ {Z{n^{2 + }}} \right]\left[ {{H_2}} \right]}}{{{{\left[ {{H^ + }} \right]}^2}}} \cr} $$
Addition of $${H_2}S{O_4}$$ will increase $$\left[ {{H^ + }} \right]$$ and
$${E_{cell}}$$ will also increase and the equilibrium will shift towards $$RHS$$