Equational Noetherianness of rigid soluble groups. (English. Russian original) Zbl 1245.20036
Algebra Logic 48, No. 2, 147-160 (2009); translation from Algebra Logika 48, No. 2, 258-279 (2009).
Summary: A group \(G\) is said to be rigid if it contains a normal series of the form \(G=G_1>G_2>\cdots>G_m>G_{m+1}=1\), whose quotients \(G_i/G_{i+1}\) are Abelian and are torsion free as right \(\mathbb Z[G/G_i]\)-modules. In studying properties of such groups, it was shown, in particular, that the above series is defined by the group uniquely. It is known that finitely generated rigid groups are equationally Noetherian: i.e., for any \(n\), every system of equations in \(x_1,\dots,x_n\) over a given group is equivalent to some of its finite subsystems. This fact is equivalent to the Zariski topology being Noetherian on \(G^n\), which allowed the dimension theory in algebraic geometry over finitely generated rigid groups to have been constructed. It is proved that every rigid group is equationally Noetherian.
MSC:
| 20F16 | Solvable groups, supersolvable groups |
| 20F70 | Algebraic geometry over groups; equations over groups |
| 20F14 | Derived series, central series, and generalizations for groups |
Keywords:
rigid groups; equationally Noetherian groups; torsion-free right modules; algebraic geometry over groups; systems of equationsReferences:
| [1] | A. Myasnikov and N. Romanovskiy, ”Krull dimension of solvable groups,” arXiv:0808.2932v1 [math.GR]; http://xxx.lanl.gov:80/abs/0808.2932v1 . · Zbl 1234.20052 |
| [2] | Ch. K. Gupta and N. S. Romanovskii, ”The property of being equationally Noetherian for some soluble groups,” Algebra Logika, 46, No. 1, 46–59 (2007). · Zbl 1156.20032 · doi:10.1007/s10469-007-0003-5 |
| [3] | I. N. Herstein, Noncommutative Rings, The Carus Math. Monogr., 15, Math. Ass. Am. (1968). |
| [4] | J. Lewin, ”A note on zero divisors in group-rings,” Proc. Am. Math. Soc., 31, No. 2, 357–359 (1972). · Zbl 0242.16006 · doi:10.1090/S0002-9939-1972-0292957-X |
| [5] | P. H. Kropholler, P. A. Linnell, and J. A. Moody, ”Applications of a new K-theoretic theorem on soluble group rings,” Proc. Am. Math. Soc., 104, No. 3, 675–684 (1988). · Zbl 0691.16013 |
| [6] | G. Baumslag, A. Myasnikov, and V. N. Remeslennikov, ”Algebraic geometry over groups. I. Algebraic sets and ideal theory,” J. Alg., 219, No. 1, 16–79 (1999). · Zbl 0938.20020 · doi:10.1006/jabr.1999.7881 |
| [7] | A. Myasnikov and V. N. Remeslennikov, ”Algebraic geometry over groups. II. Logical foundations,” J. Alg., 234, No. 1, 225–276 (2000). · Zbl 0970.20017 · doi:10.1006/jabr.2000.8414 |
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