Difference between revisions of "Freiheitssatz"
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''independence theorem'' | ''independence theorem'' | ||
A theorem originally proposed by M. Dehn in a geometrical setting and originally proven by W. Magnus [[#References|[a1]]]. This theorem is the cornerstone of one-relator [[Group|group]] theory. | A theorem originally proposed by M. Dehn in a geometrical setting and originally proven by W. Magnus [[#References|[a1]]]. This theorem is the cornerstone of one-relator [[Group|group]] theory. | ||
| − | The Freiheitssatz says the following: Let | + | The Freiheitssatz says the following: Let $G = \langle x _ { 1 } , \dots , x _ { n } : r = 1 \rangle$ be a [[Group|group]] defined by a single cyclically reduced relator $r$. If $x_{1} $ appears in $r$, then the subgroup of $G$ generated by $x _ { 2 } , \dots , x _ { n }$ is a [[Free group|free group]], freely generated by $x _ { 2 } , \dots , x _ { n }$. |
| − | In coarser language, the theorem says that if | + | In coarser language, the theorem says that if $G$ is as above, then the only relations in $x _ { 2 } , \dots , x _ { n }$ are the trivial ones. |
| − | The Freiheitssatz can be considered as a non-commutative analogue of certain more transparent results in commutative algebra. For example, suppose that | + | The Freiheitssatz can be considered as a non-commutative analogue of certain more transparent results in commutative algebra. For example, suppose that $V = K ^ { n }$ is a [[Linear space|linear space]] over a field $K$ with a basis $e _ { 1 } , \ldots , e _ { n }$. If $W = \operatorname { lin } ( w )$ is the subspace of $V$ generated by a vector $w = \sum _ { i = 1 } ^ { n } m _ { i } e _ { i }$ with $m _ { 1 } \neq 0$, then the elements $e _ { 2 } , \dots , e _ { n }$ are linearly independent modulo $W$. |
Magnus' method of proof of the Freiheitssatz relies on amalgamations (cf. also [[Amalgam|Amalgam]]; [[Amalgam of groups|Amalgam of groups]]). This method initiated the use of these products in the study of infinite discrete groups. | Magnus' method of proof of the Freiheitssatz relies on amalgamations (cf. also [[Amalgam|Amalgam]]; [[Amalgam of groups|Amalgam of groups]]). This method initiated the use of these products in the study of infinite discrete groups. | ||
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One of the by-products of Magnus' proof was an extraordinary description of the structure of these groups, which allowed him to deduce that one-relator groups have solvable word problem (cf. also [[Identity problem|Identity problem]]; [[#References|[a2]]]). | One of the by-products of Magnus' proof was an extraordinary description of the structure of these groups, which allowed him to deduce that one-relator groups have solvable word problem (cf. also [[Identity problem|Identity problem]]; [[#References|[a2]]]). | ||
| − | There are two general approaches to extending the Freiheitssatz. The first is concerned with the notion of the one-relator product | + | There are two general approaches to extending the Freiheitssatz. The first is concerned with the notion of the one-relator product $G = * A _ { i } / N ( r )$ of a family $\{ A _ { i } \}$ of groups, where the element $r$ is cyclically reduced and of syllable length at least $2$ and $N ( r )$ is its normal closure in $* A_i$. Some authors (see [[#References|[a3]]]) give conditions for the factors $A_i$ to inject into $G$. |
| − | The second approach is concerned with multi-relator versions of the Freiheitssatz (see [[#References|[a3]]] for a list of references). For example, the following strong result by N.S. Romanovskii [[#References|[a4]]] holds: Let <img align="absmiddle" border="0" src="https://www.encyclopediaofmath.org/legacyimages/f/f120/f120170/f12017027.png" /> have deficiency | + | The second approach is concerned with multi-relator versions of the Freiheitssatz (see [[#References|[a3]]] for a list of references). For example, the following strong result by N.S. Romanovskii [[#References|[a4]]] holds: Let <img align="absmiddle" border="0" src="https://www.encyclopediaofmath.org/legacyimages/f/f120/f120170/f12017027.png"/> have deficiency $d = n - m > 0$. Then there exist a subset of $d$ of the given generators which freely generates a subgroup of $G$. |
====References==== | ====References==== | ||
| − | <table>< | + | <table><tr><td valign="top">[a1]</td> <td valign="top"> W. Magnus, "Über discontinuierliche Gruppen mit einer definierenden Relation (Der Freiheitssatz)" ''J. Reine Angew. Math.'' , '''163''' (1930) pp. 141–165</td></tr><tr><td valign="top">[a2]</td> <td valign="top"> W. Magnus, "Das Identitätsproblem für Gruppen mit einer definierenden Relation" ''Math. Ann.'' , '''106''' (1932) pp. 295–307</td></tr><tr><td valign="top">[a3]</td> <td valign="top"> B. Fine, G. Rosenberger, "The Freiheitssatz and its extensions" ''Contemp. Math.'' , '''169''' (1994) pp. 213–252</td></tr><tr><td valign="top">[a4]</td> <td valign="top"> N.S. Romanovskii, "Free subgroups of finitely presented groups" ''Algebra i Logika'' , '''16''' (1977) pp. 88–97 (In Russian)</td></tr></table> |
Latest revision as of 17:46, 1 July 2020
independence theorem
A theorem originally proposed by M. Dehn in a geometrical setting and originally proven by W. Magnus [a1]. This theorem is the cornerstone of one-relator group theory.
The Freiheitssatz says the following: Let $G = \langle x _ { 1 } , \dots , x _ { n } : r = 1 \rangle$ be a group defined by a single cyclically reduced relator $r$. If $x_{1} $ appears in $r$, then the subgroup of $G$ generated by $x _ { 2 } , \dots , x _ { n }$ is a free group, freely generated by $x _ { 2 } , \dots , x _ { n }$.
In coarser language, the theorem says that if $G$ is as above, then the only relations in $x _ { 2 } , \dots , x _ { n }$ are the trivial ones.
The Freiheitssatz can be considered as a non-commutative analogue of certain more transparent results in commutative algebra. For example, suppose that $V = K ^ { n }$ is a linear space over a field $K$ with a basis $e _ { 1 } , \ldots , e _ { n }$. If $W = \operatorname { lin } ( w )$ is the subspace of $V$ generated by a vector $w = \sum _ { i = 1 } ^ { n } m _ { i } e _ { i }$ with $m _ { 1 } \neq 0$, then the elements $e _ { 2 } , \dots , e _ { n }$ are linearly independent modulo $W$.
Magnus' method of proof of the Freiheitssatz relies on amalgamations (cf. also Amalgam; Amalgam of groups). This method initiated the use of these products in the study of infinite discrete groups.
One of the by-products of Magnus' proof was an extraordinary description of the structure of these groups, which allowed him to deduce that one-relator groups have solvable word problem (cf. also Identity problem; [a2]).
There are two general approaches to extending the Freiheitssatz. The first is concerned with the notion of the one-relator product $G = * A _ { i } / N ( r )$ of a family $\{ A _ { i } \}$ of groups, where the element $r$ is cyclically reduced and of syllable length at least $2$ and $N ( r )$ is its normal closure in $* A_i$. Some authors (see [a3]) give conditions for the factors $A_i$ to inject into $G$.
The second approach is concerned with multi-relator versions of the Freiheitssatz (see [a3] for a list of references). For example, the following strong result by N.S. Romanovskii [a4] holds: Let 
have deficiency $d = n - m > 0$. Then there exist a subset of $d$ of the given generators which freely generates a subgroup of $G$.
References
| [a1] | W. Magnus, "Über discontinuierliche Gruppen mit einer definierenden Relation (Der Freiheitssatz)" J. Reine Angew. Math. , 163 (1930) pp. 141–165 |
| [a2] | W. Magnus, "Das Identitätsproblem für Gruppen mit einer definierenden Relation" Math. Ann. , 106 (1932) pp. 295–307 |
| [a3] | B. Fine, G. Rosenberger, "The Freiheitssatz and its extensions" Contemp. Math. , 169 (1994) pp. 213–252 |
| [a4] | N.S. Romanovskii, "Free subgroups of finitely presented groups" Algebra i Logika , 16 (1977) pp. 88–97 (In Russian) |
How to Cite This Entry:
Freiheitssatz. Encyclopedia of Mathematics. URL: http://encyclopediaofmath.org/index.php?title=Freiheitssatz&oldid=16698
Freiheitssatz. Encyclopedia of Mathematics. URL: http://encyclopediaofmath.org/index.php?title=Freiheitssatz&oldid=16698
This article was adapted from an original article by V.A. Roman'kov (originator), which appeared in Encyclopedia of Mathematics - ISBN 1402006098. See original article