Chemistry - How do I calculate the molarity of the Na2CO3 solution?
Solution 1:
The first part makes more sense writing moles explicitly. The first step is determining how many moles of sodium carbonate are in the original $1.00\ \mathrm g$ sample:
$$\frac{1.00\ \mathrm{g}}{286\ \mathrm{g/mol}} = 0.003447\ \mathrm{mol}$$
The second step is determining the concentration of the first $20.0\ \mathrm{mL}$ solution, i.e. what concentration results from dissolving the $0.00345\ \mathrm{mol}$ of sodium carbonate calculated above. $$\frac{0.003447\ \mathrm{mol}}{0.0200\ \mathrm{L}} = 0.174825\ \mathrm{M}$$
The third part is simply a dilution – what concentration results when we dilute the first $20.0\ \mathrm{mL}$ solution to $250\ \mathrm{mL}$: $$c_2 = \frac{c_1V_1}{V_2}$$ $$c_2 = \frac{(0.174825\ \mathrm{M})(0.020\ \mathrm{L})}{(0.250\ \mathrm{L})} = 0.0140\ \mathrm{M}$$
Solution 2:
What the question is asking is the molar concentration of the given substance after dilution with the help of values given. The first step of the answer is converting the given weight of $\ce{Na2CO3.10H2O}$ into amount of substance. For that we have a formula as \begin{align} \text{amount of substance} &= \frac{\text{mass of substance}}{\text{molecular mass of the substance}}\\ \text{amount of substance} &= \frac{ \pu{1 g}~\ce{Na2CO3.10H2O}}{\pu{286 g}~\ce{Na2CO3.10H2O}} = \pu{0.003447 mol}.\\ \end{align} We used this first step to determine the amount of substance of $\ce{Na2CO3.10H2O}$ present in the solution. It is necessary because even after dilution of the solution the amount of substance will remain constant.
The second step is converting the amount of substance into molarity. As, \begin{align} \text{molarity} &= \frac{\text{amount of substance}}{\text{volume in L}}\\ \text{molarity} &= \frac{\pu{0.003447 mol}}{\pu{0.020 L}} = \pu{0.174825 M}\\ \end{align}
The second step is done to find out the concentration of the substance in terms of molarity since the question has asked us to give the answer in molarity after dilution.
After that the given solution is diluted up to $\pu{250 mL}$, so we have to use dilution formula $$\begin{multline} \text{initial concentration}\times \text{initial volume of solution} =\\ \text{final concentration}\times \text{final volume of solution}. \end{multline}$$ So we suppose that the final concentration of the solution is $x$ and we have values for others entities. \begin{align} (\pu{0.174825 M})(\pu{0.020 L}) &= (\pu{0.250 L})(x)\\ x &= \pu{0.013986 M}\\ \end{align} This last step is carried out because after dilution the molarity of the solution changes but not the amount of substance as I stated earlier. So we equate the equation as $$\text{initial amount of substance} = \text{final amount of substance}.$$ And the final answer is $\pu{0.013986 M}$.