The Axiomatics of Free Group Rings

IF 0.1 Q4 MATHEMATICS Groups Complexity Cryptology Pub Date : 2021-12-02 DOI:10.46298/jgcc.2021.13.2.8796

B. Fine, A. Gaglione, M. Kreuzer, G. Rosenberger, D. Spellman

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引用次数: 1

Abstract

In [FGRS1,FGRS2] the relationship between the universal and elementary theory of a group ring $R[G]$ and the corresponding universal and elementary theory of the associated group $G$ and ring $R$ was examined. Here we assume that $R$ is a commutative ring with identity $1 \ne 0$. Of course, these are relative to an appropriate logical language $L_0,L_1,L_2$ for groups, rings and group rings respectively. Axiom systems for these were provided in [FGRS1]. In [FGRS1] it was proved that if $R[G]$ is elementarily equivalent to $S[H]$ with respect to $L_{2}$, then simultaneously the group $G$ is elementarily equivalent to the group $H$ with respect to $L_{0}$, and the ring $R$ is elementarily equivalent to the ring $S$ with respect to $L_{1}$. We then let $F$ be a rank $2$ free group and $\mathbb{Z}$ be the ring of integers. Examining the universal theory of the free group ring ${\mathbb Z}[F]$ the hazy conjecture was made that the universal sentences true in ${\mathbb Z}[F]$ are precisely the universal sentences true in $F$ modified appropriately for group ring theory and the converse that the universal sentences true in $F$ are the universal sentences true in ${\mathbb Z}[F]$ modified appropriately for group theory. In this paper we show this conjecture to be true in terms of axiom systems for ${\mathbb Z}[F]$.

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自由群环的公理化

在[FGRS1,FGRS2]中，研究了群环$R[G]$的全称和初等理论与相应群$G$和环$R$的全称和初等理论之间的关系。这里我们假设$R$是具有单位元$1 \ ne0 $的交换环。当然，这些都是相对于适当的逻辑语言$L_0,L_1,L_2$，分别适用于群，环和群环。这些公理系统在[FGRS1]中提供。在[FGRS1]中证明了如果$R[G]$对$L_{2}$初等等价于$S[H]$，则同时群$G$对$L_{0}$初等等价于群$H$，环$R$对$L_{1}$初等等价于环$S$。然后设$F$为秩$2$ freegroup， $\mathbb{Z}$为整数环。考察了自由群环${\mathbb Z}[F]$的全称命题，提出了${\mathbb Z}[F]$中的全称命题为真，即${\mathbb Z}[F]$中的全称命题为真，即${\mathbb Z}[F]$中全称命题为真，即${\mathbb Z}[F]$中全称命题为真，即${\mathbb Z}[F]$中全称命题为真，即${\mathbb Z}[F]$中全称命题为真，即${\mathbb Z}[F]$中全称命题为真。在本文中，我们用${\mathbbZ}[F]$的公理系统证明了这个猜想的成立。

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