Some Basic Concepts in Chemistry MCQ Questions & Answers in Physical Chemistry | Chemistry
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141.
At $$STP$$ the density of $$CC{l_4}$$ vapour in $$g/L$$ will be nearest to
142.
The density $$\left( {{\text{in}}\,g\,m{L^{ - 1}}} \right)$$ of a $${\text{3}}{\text{.60}}\,M$$ sulphuric acid solution that is $$29\% \,{H_2}S{O_4}\left( {{\text{molar}}\,{\text{mass}}\,{\text{ = }}\,98\,g\,mo{l^{ - 1}}} \right)$$ by mass will be
A
1.45
B
1.64
C
1.88
D
1.22
Answer :
1.22
$$\eqalign{
& {\text{Since molarity of}}\,{\text{solution is }}3.60{\text{ }}M{\text{. It means }}3.6{\text{ }}moles \cr
& {\text{of}}\,{H_2}S{O_4}\,{\text{is present in its 1 litre solution}}{\text{.}} \cr
& {\text{Mass of }}3.6{\text{ moles}}\,{\text{of }}{H_2}S{O_4} \cr
& = {\text{Moles }} \times {\text{ Molecular mass = }}3.6{\text{ }} \times {\text{ }}98{\text{ }}g{\text{ }} = {\text{ }}352.8{\text{ }}g \cr
& \therefore \,1000{\text{ }}ml{\text{ solution has }}352.8{\text{ }}g{\text{ of}}\,{H_2}S{O_4} \cr
& {\text{Given that }}29{\text{ }}g{\text{ of}}\,{H_2}S{O_4}\,{\text{is present in}} = 100{\text{ }}g{\text{ of}}\,{\text{solution}} \cr
& \therefore \,352.8{\text{ }}g{\text{ of}}\,{H_2}S{O_4}\,{\text{is present in}} \cr
& = \frac{{100}}{{29}} \times 352.8\,g{\text{ of solution}} = 1216{\text{ }}g{\text{ of solution}} \cr
& {\text{Density}} = \frac{{{\text{Mass}}}}{{{\text{Volume}}}} = \frac{{1216}}{{1000}} = 1.216\,g/ml = 1.22g/ml \cr} $$
143.
If potassium chlorate is $$80\% $$ pure, then $$48$$ $$g$$ of oxygen would be produced from ( atomic mass of $$K = 39$$ )
A
$$153.12\,g\,\,{\text{of}}\,\,KCl{O_3}$$
B
$$122.5\,g\,\,{\text{of}}\,\,KCl{O_3}$$
C
$$245\,g\,\,{\text{of}}\,\,KCl{O_3}$$
D
$$98\,g\,\,{\text{of}}\,\,KCl{O_3}$$
Answer :
$$153.12\,g\,\,{\text{of}}\,\,KCl{O_3}$$
\[\underset{\begin{smallmatrix}
2\times 122.5g \\
\,\,\,\,\,\,245
\end{smallmatrix}}{\mathop{2KCl{{O}_{3}}}}\,\xrightarrow{\text{heat}}2KCl+\underset{\begin{smallmatrix}
3\times 32g \\
\,\,\,\,96
\end{smallmatrix}}{\mathop{3{{O}_{2}}}}\,\]
$$48$$ $$g$$ of oxygen will be produced from $$122.5\,g$$ of $$KCl{O_3}$$
∴ Amount of $$80\% \,KCl{O_3}$$ needed
$$\eqalign{
& = \frac{{100}}{{80}} \times 122.5 \cr
& = 153.12g \cr} $$
144.
A metal oxide has the formula $${Z_2}{O_3}.$$ It can be reduced by hydrogen to give free metal and water. $$0.1596\,g$$ of the metal oxide requires $$6\,mg$$ of hydrogen for complete reduction. The atomic weight of the metal is
145.
Which of the following reactions is not correct according to the law of conservation of mass ?
A
$$2M{g_{\left( s \right)}} + {O_{2\left( g \right)}} \to 2Mg{O_{\left( s \right)}}$$
B
$${C_3}{H_{8\left( g \right)}} + {O_{2\left( g \right)}} \to C{O_{2\left( g \right)}} + {H_2}{O_{\left( g \right)}}$$
C
$${P_{4\left( s \right)}} + 5{O_{2\left( g \right)}} \to {P_4}{O_{10\left( s \right)}}$$
D
$$C{H_{4\left( g \right)}} + 2{O_{2\left( g \right)}} \to C{O_{2\left( g \right)}} + 2{H_2}{O_{\left( g \right)}}$$
Answer :
$${C_3}{H_{8\left( g \right)}} + {O_{2\left( g \right)}} \to C{O_{2\left( g \right)}} + {H_2}{O_{\left( g \right)}}$$
$${C_3}{H_8} + {O_2} \to C{O_2} + {H_2}O$$
Since the reaction is not balanced hence, mass of reactants and products are different. It is against the law of conservation of mass.
146.
An element, $$X$$ has the following isotopic composition :
$$^{200}X:\,\,90\% ,{\,^{199}}X:\,\,8.0\% ,{\,^{202}}X:2.0\% $$
The weighted average atomic mass of the naturally occurring element $$X$$ is closest to
147.
In the reaction $$4N{H_3}\left( g \right) + 5{O_2}\left( g \right) \to 4NO\left( g \right) + 6{H_2}O\left( l \right),$$ when $$1$$ $$mole$$ of ammonia and $$1$$ $$mole$$ of $${O_2}$$ are made to react to completion
A
$$1.0$$ $$mole$$ of $${H_2}O$$ is produced
B
$$1.0$$ $$mole$$ of $$NO$$ will be produced
C
all the ammonia will be consumed
D
all the oxygen will be consumed
Answer :
all the oxygen will be consumed
$$\eqalign{
& 4N{H_3}\left( g \right) + 5{O_2}\left( g \right) \to 4NO\left( g \right) + 6{H_2}O\left( l \right) \cr
& \,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,4\,moles\,\,\,\,\,\,5\,moles\,\,\,\,\,\,4\,moles\,\,\,\,\,6\,moles \cr
& {\text{Given}}\,\,\,\,\,\,\,\,\,\,\,\,\,{\text{1}}\,Mole\,\,\,\,\,\,\,\,1\,Mole \cr
& {\text{Reacting}}\,\,\,\,\,\,\,\,0.8\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,1\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,0.8\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,1.2 \cr
& {\text{All }}{O_2}\,{\text{consumed being limiting reagent}}{\text{.}} \cr} $$
148.
What volume of water is to be added to $$100\,c{m^3}$$ of $$0.5\,M\,NaOH$$ solution to make it $$0.1\,M$$ solution ?
A
$$200\,c{m^3}$$
B
$$400\,c{m^3}$$
C
$$500\,c{m^3}$$
D
$$100\,c{m^3}$$
Answer :
$$400\,c{m^3}$$
$$\eqalign{
& {M_1}{V_1} = {M_2}{V_2} \cr
& 0.5 \times 100 = 0.1 \times {V_2} \Rightarrow {V_2} = 500\,c{m^3} \cr} $$
Volume of water to be added to $$100\,c{m^3}$$ of solution $$ = 500 - 100 = 400\,c{m^3}$$
149.
The percentage weight of $$Zn$$ in white vitriol $$\left[ {ZnS{O_4}.7{H_2}O} \right]$$ is approximately equal to$$\left( {{\text{at}}.\,mass\,{\text{of}}\,Zn = 65,S = 32,} \right.O = 16$$ and $$\left. {H = 1} \right)$$
150.
Haemoglobin contains $$0.33\% $$ of iron by weight. The molecular weight of haemoglobin is approximately 67200. The number of iron atoms $$\left( {at.\,wt.\,{\text{of}}\,Fe = 56} \right)$$ present in one molecule of haemoglobin is
A
6
B
1
C
2
D
4
Answer :
4
$$\eqalign{
& {\text{Weight of Iron in 67200}} \cr
& = \frac{{0.33}}{{100}} \times 67200 \cr
& = 221.76 \cr
& {\text{Number of atoms of Iron}} \cr
& = \frac{{221.76}}{{56}} \cr
& = 3.96 \equiv 4 \cr} $$