Answer
$\pm \dfrac{1}{2}, \pm \dfrac{1}{3}, \pm \dfrac{1}{6}, \pm \dfrac{2}{3}, \pm \dfrac{4}{3}, \pm \dfrac{5}{2}, \pm \dfrac{5}{3}, \pm \dfrac{5}{6}, \pm \dfrac{10}{3}, \pm \dfrac{20}{3} \pm 1, \pm 2, \pm 4,\pm 5, \pm 10, \pm 20$
Work Step by Step
Let us consider that $m$ is a factor of the constant term and $n$ is a factor of the leading coefficient. Then the potential zeros can be expressed by the possible combinations as: $\dfrac{m}{n}$.
We see from the given polynomial function that it has a constant term of $18$ and a leading coefficient of $3$.
The possible factors $m$ of the constant term and $n$ of the leading coefficient are: $m=\pm 1, \pm 2, \pm 4, \pm 5, \pm 10, \pm 20$ and $n=\pm 1, \pm 2, \pm 3, \pm 6$
Therefore, the possible rational roots of $f(x)$ are:
$\dfrac{m}{n}=\pm \dfrac{1}{2}, \pm \dfrac{1}{3}, \pm \dfrac{1}{6}, \pm \dfrac{2}{3}, \pm \dfrac{4}{3}, \pm \dfrac{5}{2}, \pm \dfrac{5}{3}, \pm \dfrac{5}{6}, \pm \dfrac{10}{3}, \pm \dfrac{20}{3} \pm 1, \pm 2, \pm 4,\pm 5, \pm 10, \pm 20$
