MCQ
The volume strength of $1.5\,N\,{H_2}{O_2}$ solution is
- A$4.8$
- B$5.2$
- ✓$8.4$
- D$8.8$
$\underset{68 g}{2 H_{2}} O_{2} \rightarrow 2 H_{2} O+\underset{22400 m L a t}{O_{2}}$
$68 g$ of $H _{2}$ Ogives $=22400 mL$ of $O _{2}$ at $STP$
$25.5 g H_{2} O_{2}$ gives $=\frac{22400}{68} \times 25.5=8400 mL$ of $O_{2}$ at $S T P$
$25.5 g$ of $H_{2} O_{2}$ is present in $1000 m L$ of $H _{2} O _{2}$ solution $1000 mL$ of $H _{2} O _{2}$ gives $8400 mL$ of $O _{2}$ at $STP$
$1 mL$ of $H _{2} O _{2}$ gives $\frac{8400}{1000} mL$ of $O _{2}$ at $STP$
$=8.4 m L$ of $O_{2}$
Hence, volume strength of $1.5 NH _{2} O _{2}=8.4$ volume. Or mass of $H_{2} O_{2}$ in $1.5 N$ solution $=E W$ of $H_{2} O_{2} \times 1.5 N$
$=17 \times 1.5=25.5 g / L$
Hence, volume strength of $1.5 NH _{2} O _{2}$ solution $=\frac{22.4 \times 25.5}{68}=8.4$
Generate a complete, print-ready paper with questions like this in minutes — across 16+ boards, with answer keys.
$(i)\,Cl\xrightarrow{E.A.}Cl^-\,\,\,\,\,\,(ii)\,C{{l}^{-}}\xrightarrow{I.E.}Cl\,\,\,\,(iii)\,\,Cl\xrightarrow{I.E.}C{{l}^{+}}\,\,\,(iv)\,\,C{{l}^{+}}\xrightarrow{I.E.}Cl^{2+}$
${K_p} = 8 \times {10^{ - 2}}$$C{O_{2(g)}} + {C_{(s)}} \to 2C{O_{(g)}}$ ; ${K_p} = 2$
$CaC{{O}_{3(s)}}\xrightarrow{\Delta }Ca{{O}_{(s)}}+C{{O}_{2}}\uparrow $; ${{K}_{p}}=8\times {{10}^{-2}}$