0.5 Dilution

Problem : How much water would you need to prepare 600 grams of a 4% (w/w) Hydrogen Peroxide ( $H_2{O}_2$ ) solution using a solution of 20% (w/w) ?

Solution : Here,

$$g_{S_1}=600gm$$

$$y_1=4$$

$$y_2=20$$

$$y_1{g}_{S_1}=y_2{g}_{S_2}$$

$$\Rightarrow 4X600=20X{g}_{S_2}$$

$$\Rightarrow g_{S_2}=\frac{4X600}{20}=120gm$$

$$\text{Total mass of 4\%}=\text{mass of 20\% solution}+\text{mass of water added}$$

$$\text{mass of water added}=600-120=480gm$$

Problem : What volume of water should be added to 100 ml nitric acid having specific gravity 1.4 and 70% strength to give 1 M solution?

Solution : We first need to convert the given strength of concentration to molarity. Molarity is given by :

$$M=\frac{10yd}{M_O}$$

The specific gravity is 1.4 (density compared to water). Hence, density of solution is 1.4 gm/ml.

$$\Rightarrow M=\frac{10X70X1.4}{\left(1+14+3X16\right)}=15.55M$$

Applying dilution equation,

$$M_1{V}_{C{C}_1}=M_2{V}_{C{C}_2}$$

$$\Rightarrow 15.55X100=1X{V}_2$$

$$\Rightarrow V_2=1555ml$$

$$\text{The volume of water to be added}=1555-100=1455ml$$

Problem : In an experiment, 300 ml of 6.0 M nitric acid is required. Only 50 ml of pure nitric acid is available. Pure anhydrous nitric acid (100%) is a colorless liquid with a density of 1522 $kg/m^3$ . Would it be possible to carry out the experiment?

Solution : Here,

$$M_1=6M;M_2=?;V_{C{C}_1}=300ml;V_{C{C}_2}=?$$

In order to apply dilution equation, we need to know the molarity of concentrated nitric acid. Now 1 litre pure concentrate weighs 1000 X 1.522 = 1522 gm. The number of moles in 1 litre of nitric acid is :

$$\Rightarrow n_B=\frac{1522}{\left(1+14+3X16\right)}=24.16$$

Hence, molarity of the nitric acid concentrate is 24.16 M.

Applying dilution equation,

$$M_1{V}_{C{C}_1}=M_2{V}_{C{C}_2}$$

$$\Rightarrow V_{C{C}_2}=\frac{M_1{V}_{C{C}_1}}{M_2}=\frac{6X300}{24.16}=74.5ml$$

It means requirement of concentrate (74.5 ml) is more than what is available (50 ml). As such, experiment can not be completed.

Problem : A 100 ml, 0.5 M calcium nitrate solution is mixed with 200 ml of 1.25M calcium nitrate solution. Calculate the concentration of the final solution. Assume volumes to be additive.

Solution : We first calculate milli-moles for each solution. Then, add them up to get the total moles present in the solution. Finally, we divide that total moles by the total volume.

$$\text{Milli-moles in the first solution}=M_1{V}_{C{C}_1}=100X0.5=50$$

$$\text{Milli-moles in the second solution}=M_2{V}_{C{C}_2}=200X1.25=250$$

$$\text{Milli-moles in the final solution}=50+250=300$$

$$\text{Total volume of the solution}=100+200=300ml$$

Hence, molarity of the final solution is :

$$M=\frac{\text{Milli-moles of solute}}{V_{CC}}=\frac{300}{300}=1M$$

Alternative method

Molarity of the first solution when diluted to final volume of 300 ml is obtained as :

$$M_1{V}_{C{C}_1}=M_2{V}_{C{C}_2}$$

$$\Rightarrow 0.5X100=M_{2}X300$$

$$\Rightarrow M_2=\frac{50}{300}=\frac{1}{6}$$

Molarity of the second solution when diluted to final volume of 300 ml is obtained as :

$$M_1{V}_{C{C}_1}=M_2{V}_{C{C}_2}$$

$$\Rightarrow 1.25X200=M_{2}X300$$

$$\Rightarrow M_2=\frac{250}{300}=\frac{5}{6}$$

Hence, molarity of the final combined solution is :

$$M=\frac{1}{6}+\frac{5}{6}=1$$

Problem : What volume of water should be added to 100 ml sulphuric acid having specific gravity 1.1 and 80% strength to give 1 N solution?

Solution : We first need to convert the given strength of concentration to Normality. For that we first calculate molarity and then use the formula : :

$$N=xM$$

Now, molarity is given by

$$M=\frac{10yd}{M_O}$$

The specific gravity is 1.4 (density compared to water). Hence, density of solution is 1.4 gm/ml.

$$\Rightarrow M=\frac{10X80X1.1}{\left(2X1+32+4X16\right)}=8.98M$$

The valence factor of $H_{2}S{O}_4$ is 2. Hence,

$$\Rightarrow N=xM=2X8.98=17.96N$$

Applying dilution equation,

$$N_1{V}_{C{C}_1}=N_2{V}_{C{C}_2}$$

$$\Rightarrow 17.96X100=1X{V}_2$$

$$\Rightarrow V_2=1796ml$$

$$\text{The volume of water to be added}=1796-100=1696ml$$