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\iteman{ZMATH 2016a.00806}
\itemau{Clark, Pete L.; Diepeveen, Niels J.}
\itemti{Absolute convergence in ordered fields.}
\itemso{Am. Math. Mon. 121, No. 10, 909-916 (2014).}
\itemab
Let $\mathbb{F}$ be an ordered field. The authors show that the relation between convergence and absolute convergence of an infinite series $\sum_{n=1}^\infty a_n$ in $\mathbb{F}$ is closely connected to the sequential (i.e., Cauchy) completeness of the field $\mathbb{F}$. { indent=8mm \item{(i)} If $\mathbb{F}$ is sequentially complete and Archimedean, then $\mathbb{F}$ is isomorphic to $\mathbb{R}$; then, in this case, it is well known (from calculus) that every absolutely convergent series in $\mathbb{F}$ is convergent in $\mathbb{F}$, but the converse is not true, that is, $\mathbb{F}$ has a convergent series that is not absolutely convergent (e.g., let $a_n=(-1)^n/n$). \item{(ii)} If $\mathbb{F}$ is sequentially complete and non-Archimedean, then $\sum_{n=1}^\infty a_n$ converges in $\mathbb{F}$ if and only if it converges absolutely in $\mathbb{F}$. \item{(iii)} If $\mathbb{F}$ is not sequentially complete ($\mathbb{F}$ may be Archimedean, that is, isomorphic to a proper subfield of $\mathbb{R}$, or non-Archimedean), then $\mathbb{F}$ has an absolutely convergent series that is not convergent and $\mathbb{F}$ has a convergent series that is not absolutely convergent. }
\itemrv{Khodr Shamseddine (Winnipeg)}
\itemcc{I35}
\itemut{convergent series; absolutely convergent series; ordered fields; Archimedean fields; non-Archimedean fields; Cauchy completeness}
\itemli{doi:10.4169/amer.math.monthly.121.10.909}
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