Answer:
Step-by-step explanation:
The masses of the solids provide us with the following two equations.
g Al(C H NO) g Mg(C H NO) g 9 6 3 9 6 2 + = 7.815
g Al O g MgO g 2 3 + =1.002
With two equations and four unknowns, we need two additional equa-
tions to solve the problem. A conservation of mass requires that all the
aluminum in Al(C9H6NO)3 is found in Al2O3; thus
g Al O g Al(C H NO) mol Al
459.45 g Al(C 2 3 = 9 6 3
1
9 6
2 3
H NO) 2 3
g Al O
3 mol Al O
101 96
2
g Al O g Al(C H NO) 2 3 = 9 6 0 11096 3 .
Using the same approach, a conservation of mass for magnesium gives g MgO g Mg(C H NO) mol Mgg Mg(C H 9 6 29
= 1312.61 6 2 NO)g MgOmol Mg40.304
g MgO g Mg(C H NO) = 9 6 2 0.12893
Substituting the equations for g MgO and g Al2O3 into the equation for
the combined weights of MgO and Al2O3 leaves us with two equations
and two unknowns.
g Al(C H NO) g Mg(C H NO) g 9 6 3 9 6 2 + = 7.815
0 11096 0 12893 3 . . + g Al(C H NO) g Mg(C H NO) 9 6 9 6 2 =1.002 g
Multiplying the first equation by 0.11096 and subtracting the second
equation gives
− 0. . 01797 g Mg(C H NO) g = −0 1348 9 6 2
g Mg(C H NO) g 9 6 2 = 7.501
g Al(C H NO) g g Mg(C H NO) 9 6 3 9 6 2 = − 7. . 815 7 501 = 0.314 g
Now we can finish the problem using the approach from Example 8.1. A
conservation of mass requires that all the aluminum and magnesium in the
sample of Dow metal is found in the precipitates of Al(C9H6NO)3 and the
Mg(C9H6NO)2. For aluminum, we find that
0 314 1
3 . g Al(C H NO) mol Al
459.45 g Al(C H 9 696NO)g Almol Al g Al3
26 982 = 0 01844 . .
0 01844
100 3 02 . . % g Al
0.611 g sample
= w/w Al
and for magnesium we have
7 501 1 2 . g Mg(C H NO) mol Mg
312.61 g Mg(C H 9 696NO)g MgmolMgg Mg2
24 305 = 0 5832 . .
0.5832 g Mg
0.611 g sample
= 100 95. %5 w/w Mg