Difference between revisions of "Amalgam of groups"
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+ | A family of groups $ G _ \alpha , \alpha \in I $, | ||
+ | that satisfies the condition that the intersection $ G _ \alpha \cap G _ \beta $ | ||
+ | is a subgroup in $ G _ \alpha $ | ||
+ | and $ G _ \beta $ | ||
+ | for any $ \alpha , \beta $ | ||
+ | from $ I $. | ||
+ | An example of an amalgam of groups is an arbitrary family of subgroups of a given group. An imbedding of an amalgam of groups $ A = \{ {G _ \alpha } : {\alpha \in I } \} $ | ||
+ | into a group $ G $ | ||
+ | is a one-to-one mapping of the union $ \cup _ {\alpha \in I } G _ \alpha $ | ||
+ | into $ G $ | ||
+ | whose restriction to each $ G _ \alpha $ | ||
+ | is an isomorphism. An amalgam of groups in which all intersections $ G _ \alpha \cap G _ \beta $ | ||
+ | are identical (and equal to, say, a subgroup $ H $) | ||
+ | is imbeddable in the group that is the free product of the groups $ G _ \alpha $ | ||
+ | with the amalgamated subgroup $ H $. | ||
+ | On the other hand, there exists an amalgam of four Abelian groups that is not imbeddable in a group. The principal problem concerning amalgams of groups is, generally speaking, as follows. Let $ \sigma , \tau $ | ||
+ | be possible properties of groups. The question to be answered is the nature of the conditions under which an amalgam of groups with the property $ \sigma $ | ||
+ | is imbeddable in a group with the property $ \tau $. | ||
+ | It was found that all amalgams of two finite groups are imbeddable in a finite group. An amalgam of three Abelian groups is imbeddable in an Abelian group. An amalgam of four Abelian groups imbedded in a group is contained in an Abelian group. There exists an amalgam of five Abelian groups which is imbeddable in a group, but not in an Abelian group. Another problem that has been studied is the imbeddability of an amalgam of groups if $ \sigma , \tau $ | ||
+ | denote solvability, nilpotency, periodicity, local finiteness, etc. (in different combinations). | ||
====Comments==== | ====Comments==== | ||
− | In the definition of amalgam above, think of the | + | In the definition of amalgam above, think of the $ G _ \alpha $ |
+ | as all being subsets of some large set $ X $. | ||
+ | The amalgamated product of groups $ G _ {i} $" | ||
+ | over a common subgroup U" is constructed as follows. Let $ G _ {i} $ | ||
+ | be a set of groups indexed by the set $ I $. | ||
+ | For each $ i $ | ||
+ | let $ U _ {i} $ | ||
+ | be a subgroup of $ G _ {i} $ | ||
+ | and for each $ i $ | ||
+ | let there be an isomorphism $ \phi _ {i} : U _ {i} \rightarrow U $ | ||
+ | identifying $ U _ {i} $ | ||
+ | and $ U $. | ||
+ | Consider the set $ \widetilde{G} $ | ||
+ | of all words | ||
− | + | $$ | |
+ | a _ {1} \dots a _ {t} $$ | ||
− | with each | + | with each $ a _ {i} $ |
+ | from some $ G _ {j} $, | ||
+ | and consider the following elementary equivalences | ||
− | 1) if | + | 1) if $ a _ {i} = 1 $ |
+ | then $ a _ {1} \dots a _ {i-1} a _ {i} a _ {i+1} {} \dots a _ {t} $ | ||
+ | is equivalent to $ a _ {1} \dots a _ {i-1} a _ {i+1} \dots a _ {t} $; | ||
− | 2) if | + | 2) if $ a _ {i} $ |
+ | and $ a _ {i+1} $ | ||
+ | belong to the same group $ G _ {j} $ | ||
+ | and $ a _ {i} a _ {i+1} = a _ {i} ^ \prime $ | ||
+ | in $ G _ {j} $ | ||
+ | then $ a _ {1} \dots a _ {i-1} a _ {i} a _ {i+1} \dots a _ {t} $ | ||
+ | is equivalent to $ a _ {1} \dots a _ {i-1} a _ {i} ^ \prime a _ {i+2} \dots a _ {t} $; | ||
− | 3) if | + | 3) if $ a _ {i} = u _ {i} \in U _ {j} \subseteq G _ {j} $ |
+ | and $ b _ {i} = u _ {k} \in U _ {k} \subseteq G _ {k} $ | ||
+ | and $ \phi _ {k} ( u _ {k} ) = u = \phi _ {i} ( u _ {i} ) \in U $, | ||
+ | then $ a _ {1} \dots a _ {i-1} a _ {i} a _ {i+1} \dots a _ {t} $ | ||
+ | is equivalent to $ a _ {1} \dots a _ {i-1} b _ {i} a _ {i+1} \dots a _ {t} $. | ||
− | Let | + | Let $ \sim $ |
+ | be the equivalence relation generated by these elementary equivalences, then $ \widetilde{G} / \sim $ | ||
+ | is the amalgamated product of the $ G _ {i} $, | ||
+ | more precisely of the $ ( G _ {i} , U _ {i} ) $( | ||
+ | i.e. the free product with amalgamated subgroup of the $ G _ {i} $ | ||
+ | $ U $); | ||
+ | the group law is induced by concatenation. | ||
− | Amalgamated products are non-trivial. This follows from the following canonical form theorem. For each | + | Amalgamated products are non-trivial. This follows from the following canonical form theorem. For each $ i $ |
+ | select a set $ R _ {i} $ | ||
+ | of left coset representatives of $ U $ | ||
+ | in $ G _ {i} $. | ||
+ | Then each word is equivalent to precisely one of the form $ uz _ {1} \dots z _ {t} $ | ||
+ | with each $ z _ {i} $ | ||
+ | in some $ R _ {j} $, | ||
+ | $ u \in U $ | ||
+ | and $ z _ {1} $ | ||
+ | and $ z _ {i+1} $ | ||
+ | belonging to different $ G _ {j} $' | ||
+ | s for $ i = 1 \dots t-1 $. | ||
+ | If $ U = \{ e \} $ | ||
+ | one obtains of course the free product of the $ G _ {i} $. | ||
+ | A subgroup of a free product is itself a free product (Kurosh' theorem). Subgroups of a product with an amalgamated subgroup need not be themselves of this type. The reason is that if $ U $ | ||
+ | is the amalgamated subgroup, then one can take subgroups $ H _ {i} $ | ||
+ | of the $ G _ {i} $ | ||
+ | with different intersections with $ U $ | ||
+ | so that the $ H _ {i} $ | ||
+ | will amalgamate in various different ways. This leads to generalized amalgamated products and the notion of amalgam as defined above. The theory of these is still incomplete. | ||
====References==== | ====References==== | ||
<table><TR><TD valign="top">[a1]</TD> <TD valign="top"> M. Hall jr., "The theory of groups" , Macmillan (1959)</TD></TR><TR><TD valign="top">[a2]</TD> <TD valign="top"> H. Neumann, "Generalized free products with amalgamated subgroups I" ''Amer. J. Math.'' , '''70''' (1948) pp. 590–625</TD></TR><TR><TD valign="top">[a3]</TD> <TD valign="top"> H. Neumann, "Generalized free products with amalgamated subgroups II" ''Amer. J. Math.'' , '''71''' (1949) pp. 491–540</TD></TR></table> | <table><TR><TD valign="top">[a1]</TD> <TD valign="top"> M. Hall jr., "The theory of groups" , Macmillan (1959)</TD></TR><TR><TD valign="top">[a2]</TD> <TD valign="top"> H. Neumann, "Generalized free products with amalgamated subgroups I" ''Amer. J. Math.'' , '''70''' (1948) pp. 590–625</TD></TR><TR><TD valign="top">[a3]</TD> <TD valign="top"> H. Neumann, "Generalized free products with amalgamated subgroups II" ''Amer. J. Math.'' , '''71''' (1949) pp. 491–540</TD></TR></table> |
Latest revision as of 16:10, 1 April 2020
A family of groups $ G _ \alpha , \alpha \in I $,
that satisfies the condition that the intersection $ G _ \alpha \cap G _ \beta $
is a subgroup in $ G _ \alpha $
and $ G _ \beta $
for any $ \alpha , \beta $
from $ I $.
An example of an amalgam of groups is an arbitrary family of subgroups of a given group. An imbedding of an amalgam of groups $ A = \{ {G _ \alpha } : {\alpha \in I } \} $
into a group $ G $
is a one-to-one mapping of the union $ \cup _ {\alpha \in I } G _ \alpha $
into $ G $
whose restriction to each $ G _ \alpha $
is an isomorphism. An amalgam of groups in which all intersections $ G _ \alpha \cap G _ \beta $
are identical (and equal to, say, a subgroup $ H $)
is imbeddable in the group that is the free product of the groups $ G _ \alpha $
with the amalgamated subgroup $ H $.
On the other hand, there exists an amalgam of four Abelian groups that is not imbeddable in a group. The principal problem concerning amalgams of groups is, generally speaking, as follows. Let $ \sigma , \tau $
be possible properties of groups. The question to be answered is the nature of the conditions under which an amalgam of groups with the property $ \sigma $
is imbeddable in a group with the property $ \tau $.
It was found that all amalgams of two finite groups are imbeddable in a finite group. An amalgam of three Abelian groups is imbeddable in an Abelian group. An amalgam of four Abelian groups imbedded in a group is contained in an Abelian group. There exists an amalgam of five Abelian groups which is imbeddable in a group, but not in an Abelian group. Another problem that has been studied is the imbeddability of an amalgam of groups if $ \sigma , \tau $
denote solvability, nilpotency, periodicity, local finiteness, etc. (in different combinations).
Comments
In the definition of amalgam above, think of the $ G _ \alpha $ as all being subsets of some large set $ X $. The amalgamated product of groups $ G _ {i} $" over a common subgroup U" is constructed as follows. Let $ G _ {i} $ be a set of groups indexed by the set $ I $. For each $ i $ let $ U _ {i} $ be a subgroup of $ G _ {i} $ and for each $ i $ let there be an isomorphism $ \phi _ {i} : U _ {i} \rightarrow U $ identifying $ U _ {i} $ and $ U $. Consider the set $ \widetilde{G} $ of all words
$$ a _ {1} \dots a _ {t} $$
with each $ a _ {i} $ from some $ G _ {j} $, and consider the following elementary equivalences
1) if $ a _ {i} = 1 $ then $ a _ {1} \dots a _ {i-1} a _ {i} a _ {i+1} {} \dots a _ {t} $ is equivalent to $ a _ {1} \dots a _ {i-1} a _ {i+1} \dots a _ {t} $;
2) if $ a _ {i} $ and $ a _ {i+1} $ belong to the same group $ G _ {j} $ and $ a _ {i} a _ {i+1} = a _ {i} ^ \prime $ in $ G _ {j} $ then $ a _ {1} \dots a _ {i-1} a _ {i} a _ {i+1} \dots a _ {t} $ is equivalent to $ a _ {1} \dots a _ {i-1} a _ {i} ^ \prime a _ {i+2} \dots a _ {t} $;
3) if $ a _ {i} = u _ {i} \in U _ {j} \subseteq G _ {j} $ and $ b _ {i} = u _ {k} \in U _ {k} \subseteq G _ {k} $ and $ \phi _ {k} ( u _ {k} ) = u = \phi _ {i} ( u _ {i} ) \in U $, then $ a _ {1} \dots a _ {i-1} a _ {i} a _ {i+1} \dots a _ {t} $ is equivalent to $ a _ {1} \dots a _ {i-1} b _ {i} a _ {i+1} \dots a _ {t} $.
Let $ \sim $ be the equivalence relation generated by these elementary equivalences, then $ \widetilde{G} / \sim $ is the amalgamated product of the $ G _ {i} $, more precisely of the $ ( G _ {i} , U _ {i} ) $( i.e. the free product with amalgamated subgroup of the $ G _ {i} $ $ U $); the group law is induced by concatenation.
Amalgamated products are non-trivial. This follows from the following canonical form theorem. For each $ i $ select a set $ R _ {i} $ of left coset representatives of $ U $ in $ G _ {i} $. Then each word is equivalent to precisely one of the form $ uz _ {1} \dots z _ {t} $ with each $ z _ {i} $ in some $ R _ {j} $, $ u \in U $ and $ z _ {1} $ and $ z _ {i+1} $ belonging to different $ G _ {j} $' s for $ i = 1 \dots t-1 $. If $ U = \{ e \} $ one obtains of course the free product of the $ G _ {i} $. A subgroup of a free product is itself a free product (Kurosh' theorem). Subgroups of a product with an amalgamated subgroup need not be themselves of this type. The reason is that if $ U $ is the amalgamated subgroup, then one can take subgroups $ H _ {i} $ of the $ G _ {i} $ with different intersections with $ U $ so that the $ H _ {i} $ will amalgamate in various different ways. This leads to generalized amalgamated products and the notion of amalgam as defined above. The theory of these is still incomplete.
References
[a1] | M. Hall jr., "The theory of groups" , Macmillan (1959) |
[a2] | H. Neumann, "Generalized free products with amalgamated subgroups I" Amer. J. Math. , 70 (1948) pp. 590–625 |
[a3] | H. Neumann, "Generalized free products with amalgamated subgroups II" Amer. J. Math. , 71 (1949) pp. 491–540 |
Amalgam of groups. Encyclopedia of Mathematics. URL: http://encyclopediaofmath.org/index.php?title=Amalgam_of_groups&oldid=12238