{"title":"梯度wag2吸收子模块","authors":"K. Al-Zoubi, Mariam Al-Azaizeh","doi":"10.30970/ms.58.1.13-19","DOIUrl":null,"url":null,"abstract":"Let $G$ be a group with identity $e$. Let $R$ be a $G$-graded commutative ring and $M$ a graded $R$-module. In this paper, we introduce the concept of graded $WAG2$-absorbing submodule. A number of results concerning of these classes of graded submodules and their homogeneous components are given. \nLet $N=\\bigoplus _{h\\in G}N_{h}$ be a graded submodule of $M$ and $h\\in G.$ We say that $N_{h}$ is a $h$-$WAG2$-absorbing submodule of the $R_{e}$-module $M_{h}$ if $N_{h}\\neq M_{h}$; and whenever $r_{e},s_{e}\\in R_{e}$ and $m_{h}\\in M_{h}$ with $0\\neq r_{e}s_{e}m_{h}\\in N_{h}$, then either $%r_{e}^{i}m_{h}\\in N_{h}$ or $s_{e}^{j}m_{h}\\in N_{h}$ or $%(r_{e}s_{e})^{k}\\in (N_{h}:_{R_{e}}M_{h})$ for some $i,$ $j,$ $k$ $\\in\\mathbb{N}.$ We say that $N$ is {a graded }$WAG2${-absorbing submodule of }$M$ if $N\\neq M$; and whenever $r_{g},s_{h}\\in h(R)$ and $%m_{\\lambda }\\in h(M)$ with $0\\neq r_{g}s_{h}m_{\\lambda }\\in N$, then either $r_{g}^{i}m_{\\lambda }\\in N$ or $s_{h}^{j}m_{\\lambda }\\in N$ or $%(r_{g}s_{h})^{k}\\in (N:_{R}M)$ for some $i,$ $j,$ $k$ $\\in \\mathbb{N}.$ In particular, the following assertions have been proved: \nLet $R$ be a $G$-graded ring, $M$ a graded cyclic $R$-module with $%Gr((0:_{R}M))=0$ and $N$ a graded submodule of $M.$ If $N$ is a graded $WAG2$% {-absorbing submodule of }$M,$ then\\linebreak $Gr((N:_{R}M))$ is a graded $WAG2$% -absorbing ideal of $R$ (Theorem 4).Let $R_{1}$ and $R_{2}$ be a $G$-graded rings. Let $R=R_{1}\\bigoplus R_{2}$ be a $G$-graded ring and $M=M_{1}\\bigoplus M_{2}$ a graded $R$-module. Let $N_{1},$ $N_{2}$ be a proper graded submodule of $M_{1}$, $M_{2}$ respectively. If $N=N_{1}\\bigoplus N_{2}$ is a graded $WAG2$-absorbing submodule of $M,$ then $N_{1}$ and $N_{2}$ are graded weakly primary submodule of $R_{1}$-module $M_{1},$ $R_{2}$-module $M_{2},$ respectively. Moreover, If $N_{2}\\neq 0$ $(N_{1}\\neq 0),$ then $N_{1}$ is a graded weak primary submodule of $R_{1}$-module $M_{1}$ $(N_{2}$ is a graded weak primary submodule of $R_{2}$-module $M_{2})$ (Theorem 7).","PeriodicalId":37555,"journal":{"name":"Matematychni Studii","volume":null,"pages":null},"PeriodicalIF":0.0000,"publicationDate":"2022-10-31","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"0","resultStr":"{\"title\":\"On graded WAG2-absorbing submodule\",\"authors\":\"K. Al-Zoubi, Mariam Al-Azaizeh\",\"doi\":\"10.30970/ms.58.1.13-19\",\"DOIUrl\":null,\"url\":null,\"abstract\":\"Let $G$ be a group with identity $e$. Let $R$ be a $G$-graded commutative ring and $M$ a graded $R$-module. In this paper, we introduce the concept of graded $WAG2$-absorbing submodule. A number of results concerning of these classes of graded submodules and their homogeneous components are given. \\nLet $N=\\\\bigoplus _{h\\\\in G}N_{h}$ be a graded submodule of $M$ and $h\\\\in G.$ We say that $N_{h}$ is a $h$-$WAG2$-absorbing submodule of the $R_{e}$-module $M_{h}$ if $N_{h}\\\\neq M_{h}$; and whenever $r_{e},s_{e}\\\\in R_{e}$ and $m_{h}\\\\in M_{h}$ with $0\\\\neq r_{e}s_{e}m_{h}\\\\in N_{h}$, then either $%r_{e}^{i}m_{h}\\\\in N_{h}$ or $s_{e}^{j}m_{h}\\\\in N_{h}$ or $%(r_{e}s_{e})^{k}\\\\in (N_{h}:_{R_{e}}M_{h})$ for some $i,$ $j,$ $k$ $\\\\in\\\\mathbb{N}.$ We say that $N$ is {a graded }$WAG2${-absorbing submodule of }$M$ if $N\\\\neq M$; and whenever $r_{g},s_{h}\\\\in h(R)$ and $%m_{\\\\lambda }\\\\in h(M)$ with $0\\\\neq r_{g}s_{h}m_{\\\\lambda }\\\\in N$, then either $r_{g}^{i}m_{\\\\lambda }\\\\in N$ or $s_{h}^{j}m_{\\\\lambda }\\\\in N$ or $%(r_{g}s_{h})^{k}\\\\in (N:_{R}M)$ for some $i,$ $j,$ $k$ $\\\\in \\\\mathbb{N}.$ In particular, the following assertions have been proved: \\nLet $R$ be a $G$-graded ring, $M$ a graded cyclic $R$-module with $%Gr((0:_{R}M))=0$ and $N$ a graded submodule of $M.$ If $N$ is a graded $WAG2$% {-absorbing submodule of }$M,$ then\\\\linebreak $Gr((N:_{R}M))$ is a graded $WAG2$% -absorbing ideal of $R$ (Theorem 4).Let $R_{1}$ and $R_{2}$ be a $G$-graded rings. Let $R=R_{1}\\\\bigoplus R_{2}$ be a $G$-graded ring and $M=M_{1}\\\\bigoplus M_{2}$ a graded $R$-module. Let $N_{1},$ $N_{2}$ be a proper graded submodule of $M_{1}$, $M_{2}$ respectively. If $N=N_{1}\\\\bigoplus N_{2}$ is a graded $WAG2$-absorbing submodule of $M,$ then $N_{1}$ and $N_{2}$ are graded weakly primary submodule of $R_{1}$-module $M_{1},$ $R_{2}$-module $M_{2},$ respectively. Moreover, If $N_{2}\\\\neq 0$ $(N_{1}\\\\neq 0),$ then $N_{1}$ is a graded weak primary submodule of $R_{1}$-module $M_{1}$ $(N_{2}$ is a graded weak primary submodule of $R_{2}$-module $M_{2})$ (Theorem 7).\",\"PeriodicalId\":37555,\"journal\":{\"name\":\"Matematychni Studii\",\"volume\":null,\"pages\":null},\"PeriodicalIF\":0.0000,\"publicationDate\":\"2022-10-31\",\"publicationTypes\":\"Journal Article\",\"fieldsOfStudy\":null,\"isOpenAccess\":false,\"openAccessPdf\":\"\",\"citationCount\":\"0\",\"resultStr\":null,\"platform\":\"Semanticscholar\",\"paperid\":null,\"PeriodicalName\":\"Matematychni Studii\",\"FirstCategoryId\":\"1085\",\"ListUrlMain\":\"https://doi.org/10.30970/ms.58.1.13-19\",\"RegionNum\":0,\"RegionCategory\":null,\"ArticlePicture\":[],\"TitleCN\":null,\"AbstractTextCN\":null,\"PMCID\":null,\"EPubDate\":\"\",\"PubModel\":\"\",\"JCR\":\"Q3\",\"JCRName\":\"Mathematics\",\"Score\":null,\"Total\":0}","platform":"Semanticscholar","paperid":null,"PeriodicalName":"Matematychni Studii","FirstCategoryId":"1085","ListUrlMain":"https://doi.org/10.30970/ms.58.1.13-19","RegionNum":0,"RegionCategory":null,"ArticlePicture":[],"TitleCN":null,"AbstractTextCN":null,"PMCID":null,"EPubDate":"","PubModel":"","JCR":"Q3","JCRName":"Mathematics","Score":null,"Total":0}
Let $G$ be a group with identity $e$. Let $R$ be a $G$-graded commutative ring and $M$ a graded $R$-module. In this paper, we introduce the concept of graded $WAG2$-absorbing submodule. A number of results concerning of these classes of graded submodules and their homogeneous components are given.
Let $N=\bigoplus _{h\in G}N_{h}$ be a graded submodule of $M$ and $h\in G.$ We say that $N_{h}$ is a $h$-$WAG2$-absorbing submodule of the $R_{e}$-module $M_{h}$ if $N_{h}\neq M_{h}$; and whenever $r_{e},s_{e}\in R_{e}$ and $m_{h}\in M_{h}$ with $0\neq r_{e}s_{e}m_{h}\in N_{h}$, then either $%r_{e}^{i}m_{h}\in N_{h}$ or $s_{e}^{j}m_{h}\in N_{h}$ or $%(r_{e}s_{e})^{k}\in (N_{h}:_{R_{e}}M_{h})$ for some $i,$ $j,$ $k$ $\in\mathbb{N}.$ We say that $N$ is {a graded }$WAG2${-absorbing submodule of }$M$ if $N\neq M$; and whenever $r_{g},s_{h}\in h(R)$ and $%m_{\lambda }\in h(M)$ with $0\neq r_{g}s_{h}m_{\lambda }\in N$, then either $r_{g}^{i}m_{\lambda }\in N$ or $s_{h}^{j}m_{\lambda }\in N$ or $%(r_{g}s_{h})^{k}\in (N:_{R}M)$ for some $i,$ $j,$ $k$ $\in \mathbb{N}.$ In particular, the following assertions have been proved:
Let $R$ be a $G$-graded ring, $M$ a graded cyclic $R$-module with $%Gr((0:_{R}M))=0$ and $N$ a graded submodule of $M.$ If $N$ is a graded $WAG2$% {-absorbing submodule of }$M,$ then\linebreak $Gr((N:_{R}M))$ is a graded $WAG2$% -absorbing ideal of $R$ (Theorem 4).Let $R_{1}$ and $R_{2}$ be a $G$-graded rings. Let $R=R_{1}\bigoplus R_{2}$ be a $G$-graded ring and $M=M_{1}\bigoplus M_{2}$ a graded $R$-module. Let $N_{1},$ $N_{2}$ be a proper graded submodule of $M_{1}$, $M_{2}$ respectively. If $N=N_{1}\bigoplus N_{2}$ is a graded $WAG2$-absorbing submodule of $M,$ then $N_{1}$ and $N_{2}$ are graded weakly primary submodule of $R_{1}$-module $M_{1},$ $R_{2}$-module $M_{2},$ respectively. Moreover, If $N_{2}\neq 0$ $(N_{1}\neq 0),$ then $N_{1}$ is a graded weak primary submodule of $R_{1}$-module $M_{1}$ $(N_{2}$ is a graded weak primary submodule of $R_{2}$-module $M_{2})$ (Theorem 7).