How do you balance #Ac(OH)_3(s) -> Ac_2O_3 + 3H_2O#?

1 Answer
Truong-Son N.
Apr 12, 2016

It's already partially balanced. All you need is a #2# on #"Ac"("OH")_3(s)#.

Not much is known about #"Ac"_2"O"_3# or #"Ac"("OH")_3#... but here's what I found.

This reaction is a thermal decomposition that occurs at #1100^@ "C"#. The melting point of #"Ac"_2"O"_3# is estimated to be #1227^@ "C"#.

Thus, we can expect that, if the temperature didn't change significantly from #1100^@ "C"#, the products are solid #"Ac"_2"O"_3# and gaseous #"H"_2"O"#.

Your reaction probably started out like this:

#"Ac"("OH")_3(s) stackrel(Delta" ")(->) "Ac"_2"O"_3(s) + "H"_2"O"(g)#

Given 3 hydrogens on the left, you need to notice that the common multiple of #2# and #3# is #6#. Thus, multiply #3# by #2# and #2# by #3#, meaning that you need two molecules of #"Ac"("OH")_3#.

#2"Ac"("OH")_3(s) stackrel(Delta" ")(->) "Ac"_2"O"_3(s) + "H"_2"O"(g)#

Then, as we just said, you need to multiply #2# by #3#, so you need three water molecules.

#color(blue)(2"Ac"("OH")_3(s) stackrel(Delta" ")(->) "Ac"_2"O"_3(s) + 3"H"_2"O"(g))#

At this point you are done. Tally:

  • #"Ac"#: 2 vs. 2
  • #"O"#: 2x3 vs. 3+3x1
  • #"H"#: 2x3 vs. 3x2

Thus, it is balanced.

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