Does the Series ∑(1/e^(ln(k)^2)) from k=1 to Infinity Converge?

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SUMMARY

The series ∑(1/e^(ln(k)^2)) from k=1 to infinity converges. The initial attempts using the ratio test and root test yielded inconclusive results, both returning a value of 1. However, applying the Cauchy condensation test confirmed convergence, as the terms are strictly nonincreasing. A comparison to a p-series also serves as a valid method for determining convergence.

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I am having difficulty determining whether or not the following sequence can be classified as convergent or divergent:

^{\infty}_{k=1}{\sum}\frac{1}{k^{ln(k)}}

This can be simplified to:

^{\infty}_{k=1}{\sum}\frac{1}{e^{{ln(k)}^{2}}}

Both the ratio test and root test are inconclusive (giving values of 1), while attempting the integral test doesn't work as I am unable to integrate this as a function.

Any suggestions?
 
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If by k, you mean n, then consider the following.
<br /> y = e^{(ln n)^2} \rightarrow<br /> y&#039; = y \frac{2 \ln n}{n} &gt; 0.<br />

Therefore, the terms are strictly nonincreasing.

Consider the following:

http://en.wikipedia.org/wiki/Cauchy_condensation_test

I'm sure you can do the rest.
 
Yes, by n I meant k.

I have actually never encountered the Cauchy condensation test until now.

I was able to finish it. Thank you very much.
 
A comparison to a p-series would have also worked.
 

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