Solution to Elementary Analysis: The Theory of Calculus Second Edition Section 8 Exercise 8.1
Solution:
Part a
Let $\epsilon>0$ and let $N=\dfrac{1}{\epsilon}$. Then $n>N$ implies
$$
\frac{1}{n}<\frac{1}{N}=\epsilon,
$$ and hence
$$
\left|\dfrac{(-1)^n}{n}-0\right|=\frac{1}{n}<\epsilon
$$ as desired. Therefore $\lim\dfrac{(-1)^n}{n}=0$.
Part b
Let $\epsilon>0$ and let $N=\dfrac{1}{\epsilon^3}$. Then $n>N$ implies
$$
\frac{1}{n^{1/3}}<\dfrac{1}{N^{1/3}}=\frac{1}{1/\epsilon}=\epsilon.
$$ and hence
$$
\left|\frac{1}{n^{1/3}}-0\right|=\frac{1}{n^{1/3}}<\epsilon.
$$ as desired. Therefore $\lim\dfrac{1}{n^{1/3}}=0$.
Part c
Let $\epsilon>0$ and let $N=\dfrac{7}{9\epsilon}$. Then $n>N$ implies
$$
\frac{7}{9n+6}<\frac{7}{9N}=\epsilon.
$$ and hence
\begin{align*}
\left|\frac{2n-1}{3n+2}-\frac{2}{3}\right|=\frac{7}{9n+6}<\epsilon.
\end{align*} as desired. Therefore $\lim\dfrac{2n-1}{3n+2}=\dfrac{2}{3}$.
Part d
Let $\epsilon>0$ and let $N=6+\dfrac{1}{\epsilon}$. Then $n>N$ implies
$$
0<\frac{n+6}{n^2-6}<\frac{n+6}{n^2-36}=\frac{1}{n-6}<\frac{1}{N-6}=\epsilon,
$$ and hence
$$
\left|\frac{n+6}{n^2-6}-0\right|=\frac{n+6}{n^2-6}<\epsilon
$$ as desired. Therefore $\lim\dfrac{n+6}{n^2-6}=0$.