Question #a0387
1 Answer
The answer is (2)
Explanation:
The idea here is that you're going to observe a smaller molar mass for silver nitrate because some of the salt will dissociate when dissolved in water to produce silver(I) cations and nitrate anions in aqueous solution.
#"AgNO"_ (3(aq)) -> "Ag"_ ((aq))^(+) + "NO"_ (3(aq))^(-)#
Notice that every mole of silver nitrate that dissociates in solution produces
Now, let's say that your sample has a mass of
You can express the molar mass of the salt, which represents the mass of exactly
#M_M = m/n#
You calculate that silver nitrate has a molar mass of
#170 color(red)(cancel(color(black)("g mol"^(-1)))) = (m color(red)(cancel(color(black)("g"))))/(n color(red)(cancel(color(black)("moles"))))#
#170 = m/n" "color(orange)("(*)")#
At this point, you dissolve the sample in water. Let's say that
You can say that the solution will contain
#1 - f * n -># the number of moles of silver nitrate that do not dissociate
#color(red)(2) * f * n -># the number of moles of ions produced in solution
The total number of moles of solute, dissociate and undissociated, present in the solution is equal to
#1 - fn + color(red)(2) * fn = 1 + fn#
At this point, you observe that the molar mass comes out to be
#92.64 color(red)(cancel(color(black)("g mol"^(-1)))) = (m color(red)(cancel(color(black)("g"))))/( (1 + fn)color(red)(cancel(color(black)("moles"))))#
#92.64 = m/(1 + fn)" "color(darkorange)("(* *)")#
Notice that we have two equations with three unknowns, the mass of the sample, the number of moles it contains, and the fraction that dissociates.
In order to be able to calculate the value of
To make the calculations easier, let's say that we're working with
#"170 g AgNO"_3 " " -> " " "1 mole AgNO"_3#
At this point, you will have
#{(m= "170 g"), (n = "1 mole") :}#
Plug this into equation
#92.64 = 170/(1 + f * 1)#
#1 + f = 170/92.64#
#f = 170/92.64 - 1 = 0.835#
So, you know that a fraction equal to
#color(darkgreen)(ul(color(black)("% dissociation" = 83.5%)))#
