Show that $sum_n (1-e^{-1/n})$ diverges

Question

I'm stuck in showing that $sum_n (1-e^{-1/n})$ diverges. The ratio and the root test are inconclusive. Possibly the comparison test is the way to go, but I can't find a proper bound. I got
$$
1-frac{1}{e^{1/n}}>1-frac{1}{2^{1/n}}
$$
but still I can't see here if the last implied series diverges.

Alex · Answer

Rewrite the integrand as
$$
e^{log big(frac{exp(frac{1}{n}) -1}{exp(frac{1}{n})}big)}  = e^{log (e^{frac{1}{n}}-1) - frac{1}{n}} > e^{0-frac{1}{n}}
$$
since $forall n>0   e^{frac{1}{n}}>1$ hence $log$ is positive. This can be compared to the corresponding integral:
$$
int_{1}^{infty}e^{-frac{1}{x}}dx
$$
which diverges.

Hagen von Eitzen · Answer

If you want an inequality about the exponential function,
$$ e^xge 1+x$$
is your best friend. So
$$ e^{frac1n}ge 1+frac1n=frac{n+1}{n}$$
and
$$e^{-frac1n}=frac1{e^{frac1n}}le frac n{n+1}=1-frac1{n+1},$$
making
$$ 1-e^{-frac1n}ge frac1{n+1}.$$

Show that $sum_n (1-e^{-1/n})$ diverges

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