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\begin{align}
&\bbox[10px,#ffd]{\sum_{n = 1}^{\infty}\pars{{1 \over 3n + 1} - {1 \over 3n + 2}}} =
\sum_{n = 1}^{\infty}{1 \over \pars{3n + 2}\pars{3n + 1}}
\\[5mm] = &\
\sum_{n = 0}^{\infty}{1 \over \pars{3n + 5}\pars{3n + 4}} =
{1 \over 9}\sum_{n = 0}^{\infty}{1 \over \pars{n + 5/3}\pars{n + 4/3}}
\\[5mm] = &\
{1 \over 9}\,{\Psi\pars{5/3} - \Psi\pars{4/3} \over 5/3 - 4/3}
=
{1 \over 3}\bracks{\Psi\pars{{2 \over 3}} + {1 \over 2/3} -
\Psi\pars{{1 \over 3}} - {1 \over 1/3}}
\\[5mm] & =
-\,{1 \over 2} +
{1 \over 3}\
\underbrace{\bracks{\Psi\pars{{2 \over 3}} -
\Psi\pars{{1 \over 3}}}}_{\ds{\pi\cot\pars{\pi\,{1 \over 3}} =
{\root{3} \over 3}\,\pi}}\quad\pars{~Euler\ Reflection\ Formula~}
\\[5mm] & =
\fbox{$\ds{{\root{3} \over 9}\,\pi - \half}$} \approx 0.1046
\end{align}
$\Psi\pars{z}$ is the digamma function where we used its recurrence relation and the Euler identity.