1. Molarity of Ni in 20.0 mL water is 2.24 x 10⁻³ M
2. Amount of Ni in grams in the sample 2.63 x 10⁻³ g
3. Percentage of Ni in the sample 0.0417%
1. We can solve this part by using the dilution equation, then determining the molarity
The dilution equation:
[tex](C_{1})(V_{1})=(C_{2})(V_{2})[/tex]
Here, the final concentration (6.56 ppm), final volume (100.0 mL) and initial volume (5.00) is known (note that we are not using 20.0 mL in initial volume; as 5.00 mL was taken from it, so the concentration of 5 mL will be the same as of 20.0 mL).
[tex](C_{1})(5.00mL)=(6.56ppm)(100.0mL)\\ \\ C_{1}= 131 ppm[/tex]
For the molarity of Ni
[tex]M_{Ni} = \frac{ppm (\frac{mg}{L}) }{molar mass (\frac{g}{moles}) .(1000\frac{mg}{g}) }\\ \\ M_{Ni} = \frac{131 (\frac{mg}{L})}{58.6934 (\frac{g}{moles}) .(1000\frac{mg}{g})}\\ \\ M_{Ni} =2.24X10^{-3}\frac{mol}{L}[/tex]
2. Mass in grams can be obtained from the Molarity of Ni in 20.0 mL of water
[tex]Molarity=\frac{moles}{Volume (L)}\\ \\ Moles=(Volume (L))(Molarity)\\ \\ Moles=(0.02)(0.00224)\\ \\ Moles= 4.48X10^{-5} mol[/tex]
These moles can be used to determine the mass of Ni,
[tex]n_{Ni}= \frac{mass}{molar mass}\\ \\ mass of Ni = (4.48X10^{-5})(58.6934)\\ \\ mass of Ni =2.63X10^{-3}[/tex]
3. Weight percent can be calculated by the mass determined in second part of the question
[tex]Percent Wof Ni=(\frac{mass of Ni}{mass of sample}).100\\\\ Percent W of Ni=(\frac{2.63X10^{-3}}{6.30}).100\\ \\ Percent Wof Ni=0.0417[/tex]
The percentage of Ni in the sample is found to be 0.0417 %
