tl;dr: Raising a power to a power is not commutative for a complex exponential. The two expressions are not equal to each other. Both answers happen to be correct. Since this is only an interesting ...

\displaystyle\frac{{{16}\sqrt{{n}}}}{{n}} Explanation: This question is much easier than it first appears, because there are like factors which can be cancelled. \displaystyle\frac{{{4}{n}^{{-\frac{{1}}{{2}}}}\times{4}\cancel{{{n}^{{\frac{{3}}{{2}}}}}}}}{\cancel{{{n}^{{\frac{{3}}{{2}}}}}}}\ \text{ }\ \leftarrow ...

You divide the numbers, and subtract the 10-powers: Explanation: \displaystyle=\frac{{8.4}}{{2.1}}\times\frac{{10}^{{2}}}{{10}^{{5}}}=\frac{{8.4}}{{2.1}}\times{10}^{{{2}-{5}}}={4}\times{10}^{{-{3}}}

Pankaj Solanki Sep 19, 2017 \displaystyle\frac{{{15}\cdot{10}^{{-{{8}}}}}}{{{5}\cdot{10}^{{-{{5}}}}}}=\frac{{15}}{{5}}\cdot{10}^{{-{8}-{\left(-{5}\right)}}}={3}\cdot{10}^{{-{8}+{5}}}={3}\cdot{10}^{{-{{3}}}}

\displaystyle{b}^{{6}} Explanation: \displaystyle\frac{{{\left({a}^{{-{{1}}}}\right)}{b}^{{2}}}}{{{a}{b}}}\times\frac{{{a}^{{2}}{b}^{{3}}}}{{{b}^{{-{{2}}}}}} Use the law of indices \displaystyle{x}^{{-{{m}}}}=\frac{{1}}{{x}^{{m}}} ...

See the entire simplification process below: Explanation: First, rewrite this expression as: \displaystyle{\left(\frac{{5.184}}{{7.2}}\right)}\times{\left(\frac{{10}^{{-{{5}}}}}{{10}^{{3}}}\right)}={0.72}\times{\left(\frac{{10}^{{-{{5}}}}}{{10}^{{3}}}\right)} ...