{"title":"On the square of the antipode in a connected filtered Hopf algebra","authors":"Darij Grinberg","doi":"10.46298/cm.10431","DOIUrl":null,"url":null,"abstract":"It is well-known that the antipode $S$ of a commutative or cocommutative Hopf\nalgebra satisfies $S^{2}=\\operatorname*{id}$ (where $S^{2}=S\\circ S$).\nRecently, similar results have been obtained by Aguiar, Lauve and Mahajan for\nconnected graded Hopf algebras: Namely, if $H$ is a connected graded Hopf\nalgebra with grading $H=\\bigoplus_{n\\geq0}H_n$, then each positive integer $n$\nsatisfies $\\left( \\operatorname*{id}-S^2\\right)^n \\left( H_n\\right) =0$ and\n(even stronger) \\[ \\left( \\left( \\operatorname{id}+S\\right) \\circ\\left(\n\\operatorname{id}-S^2\\right)^{n-1}\\right) \\left( H_n\\right) = 0. \\] For some\nspecific $H$'s such as the Malvenuto--Reutenauer Hopf algebra\n$\\operatorname{FQSym}$, the exponents can be lowered.\n In this note, we generalize these results in several directions: We replace\nthe base field by a commutative ring, replace the Hopf algebra by a coalgebra\n(actually, a slightly more general object, with no coassociativity required),\nand replace both $\\operatorname{id}$ and $S^2$ by \"coalgebra homomorphisms\" (of\nsorts). Specializing back to connected graded Hopf algebras, we show that the\nexponent $n$ in the identity $\\left( \\operatorname{id}-S^2\\right) ^n \\left(\nH_n\\right) =0$ can be lowered to $n-1$ (for $n>1$) if and only if $\\left(\n\\operatorname{id} - S^2\\right) \\left( H_2\\right) =0$. (A sufficient condition\nfor this is that every pair of elements of $H_1$ commutes; this is satisfied,\ne.g., for $\\operatorname{FQSym}$.)","PeriodicalId":37836,"journal":{"name":"Communications in Mathematics","volume":" ","pages":""},"PeriodicalIF":0.0000,"publicationDate":"2021-09-05","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"1","resultStr":null,"platform":"Semanticscholar","paperid":null,"PeriodicalName":"Communications in Mathematics","FirstCategoryId":"1085","ListUrlMain":"https://doi.org/10.46298/cm.10431","RegionNum":0,"RegionCategory":null,"ArticlePicture":[],"TitleCN":null,"AbstractTextCN":null,"PMCID":null,"EPubDate":"","PubModel":"","JCR":"Q3","JCRName":"Mathematics","Score":null,"Total":0}
引用次数: 1
Abstract
It is well-known that the antipode $S$ of a commutative or cocommutative Hopf
algebra satisfies $S^{2}=\operatorname*{id}$ (where $S^{2}=S\circ S$).
Recently, similar results have been obtained by Aguiar, Lauve and Mahajan for
connected graded Hopf algebras: Namely, if $H$ is a connected graded Hopf
algebra with grading $H=\bigoplus_{n\geq0}H_n$, then each positive integer $n$
satisfies $\left( \operatorname*{id}-S^2\right)^n \left( H_n\right) =0$ and
(even stronger) \[ \left( \left( \operatorname{id}+S\right) \circ\left(
\operatorname{id}-S^2\right)^{n-1}\right) \left( H_n\right) = 0. \] For some
specific $H$'s such as the Malvenuto--Reutenauer Hopf algebra
$\operatorname{FQSym}$, the exponents can be lowered.
In this note, we generalize these results in several directions: We replace
the base field by a commutative ring, replace the Hopf algebra by a coalgebra
(actually, a slightly more general object, with no coassociativity required),
and replace both $\operatorname{id}$ and $S^2$ by "coalgebra homomorphisms" (of
sorts). Specializing back to connected graded Hopf algebras, we show that the
exponent $n$ in the identity $\left( \operatorname{id}-S^2\right) ^n \left(
H_n\right) =0$ can be lowered to $n-1$ (for $n>1$) if and only if $\left(
\operatorname{id} - S^2\right) \left( H_2\right) =0$. (A sufficient condition
for this is that every pair of elements of $H_1$ commutes; this is satisfied,
e.g., for $\operatorname{FQSym}$.)
期刊介绍:
Communications in Mathematics publishes research and survey papers in all areas of pure and applied mathematics. To be acceptable for publication, the paper must be significant, original and correct. High quality review papers of interest to a wide range of scientists in mathematics and its applications are equally welcome.