Abstract
References
- G. Agnarsson, On a class of presentations of matrix algebras, Comm. Algebra, 24(14) (1996), 4331-4338.
- G. Agnarsson, S. A. Amitsur and J. C. Robson, Recognition of matrix rings II, Israel J. Math., 96(part A) (1996), 1-13.
- F. W. Anderson and K. R. Fuller, Rings and Categories of Modules, Second edition, Graduate Texts in Mathematics, 13, Springer-Verlag, New York, 1992.
- G. M. Bergman, The diamond lemma for ring theory, Adv. in Math., 29(2) (1978), 178-218.
- A. W. Chatters, Matrices, idealisers and integer quaternions, J. Algebra, 150(1) (1992), 45-56.
- A. W. Chatters, Nonisomorphic rings with isomorphic matrix rings, Proc. Edinburgh Math. Soc. (Ser. 2), 36(2) (1993), 339-348.
- T. Y. Lam, Lectures on Modules and Rings, Graduate Texts in Mathematics, 189. Springer-Verlag, New York, 1999.
- T. Y. Lam and A. Leroy, Recognition and computations of matrix rings, Israel J. Math., 96(part B) (1996), 379-397.
- J. C. Robson, Recognition of matrix rings, Comm. Algebra, 19(7) (1991), 2113- 2124.
- L. H. Rowen, Ring Theory: Student Edition, Academic Press, Inc., Boston, MA, 1991.
- S. P. Smith, An example of a ring Morita equivalent to the Weyl algebra A1, J. Algebra, 73(2) (1981), 552-555.
Abstract
Recognizing when a ring is a complete matrix ring is of significant importance in algebra. It is well-known folklore that a ring $R$ is a complete $n\times n$ matrix ring, so $R\cong M_{n}(S)$ for some ring $S$, if and only if it contains a set of $n\times n$ matrix units $\{e_{ij}\}_{i,j=1}^n$. A more recent and less known result states that a ring $R$ is a complete $(m+n)\times(m+n)$ matrix ring if and only if, $R$ contains three elements, $a$, $b$, and $f$, satisfying the two relations $af^m+f^nb=1$ and $f^{m+n}=0$. In many instances the two elements $a$ and $b$ can be replaced by appropriate powers $a^i$ and $a^j$ of a single element $a$ respectively. In general very little is known about the structure of the ring $S$. In this article we study in depth the case $m=n=1$ when $R\cong M_2(S)$. More specifically we study the universal algebra over a commutative ring $A$ with elements $x$ and $y$ that satisfy the relations $x^iy+yx^j=1$ and $y^2=0$. We describe completely the structure of these $A$-algebras and their underlying rings when $\gcd(i,j)=1$. Finally we obtain results that fully determine when there are surjections onto $M_2(\field)$ when $\field$ is a base field $\rats$ or $\ints_p$ for a prime number $p$.
Keywords
References
- G. Agnarsson, On a class of presentations of matrix algebras, Comm. Algebra, 24(14) (1996), 4331-4338.
- G. Agnarsson, S. A. Amitsur and J. C. Robson, Recognition of matrix rings II, Israel J. Math., 96(part A) (1996), 1-13.
- F. W. Anderson and K. R. Fuller, Rings and Categories of Modules, Second edition, Graduate Texts in Mathematics, 13, Springer-Verlag, New York, 1992.
- G. M. Bergman, The diamond lemma for ring theory, Adv. in Math., 29(2) (1978), 178-218.
- A. W. Chatters, Matrices, idealisers and integer quaternions, J. Algebra, 150(1) (1992), 45-56.
- A. W. Chatters, Nonisomorphic rings with isomorphic matrix rings, Proc. Edinburgh Math. Soc. (Ser. 2), 36(2) (1993), 339-348.
- T. Y. Lam, Lectures on Modules and Rings, Graduate Texts in Mathematics, 189. Springer-Verlag, New York, 1999.
- T. Y. Lam and A. Leroy, Recognition and computations of matrix rings, Israel J. Math., 96(part B) (1996), 379-397.
- J. C. Robson, Recognition of matrix rings, Comm. Algebra, 19(7) (1991), 2113- 2124.
- L. H. Rowen, Ring Theory: Student Edition, Academic Press, Inc., Boston, MA, 1991.
- S. P. Smith, An example of a ring Morita equivalent to the Weyl algebra A1, J. Algebra, 73(2) (1981), 552-555.
Details
| Primary Language | English |
|---|---|
| Subjects | Mathematical Sciences |
| Journal Section | Articles |
| Authors | |
| Publication Date | January 7, 2020 |
| Published in Issue | Year 2020 Volume: 27 Issue: 27 |