Difference between revisions of "Whitehead problem"
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| − | In 1973, S. Shelah [[#References|[a5]]] proved that it is undecidable under the axioms of Zermelo–Frankel set theory (cf. also [[Set theory|Set theory]]), ZFC, whether every Whitehead group of cardinality | + | {{TEX|auto}} |
| + | {{TEX|done}} | ||
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| + | A problem attributed, to J.H.C. Whitehead, which asks for a characterization of Abelian groups $ A $ | ||
| + | that satisfy the homological condition $ { \mathop{\rm Ext} } ( A, \mathbf Z ) = 0 $, | ||
| + | where $ \mathbf Z $ | ||
| + | is the group of integers under addition (cf. also [[Homology|Homology]]). A group which satisfies this condition is called a Whitehead group. An equivalent characterization is: $ A $ | ||
| + | is a Whitehead group if and only if for every surjective homomorphism $ \pi $ | ||
| + | onto $ A $, | ||
| + | if the kernel of $ \pi $ | ||
| + | is isomorphic to $ \mathbf Z $, | ||
| + | then the kernel is a direct summand of the domain of $ \pi $. | ||
| + | A sufficient condition for $ A $ | ||
| + | to be a Whitehead group is that $ A $ | ||
| + | is free (see [[Free Abelian group|Free Abelian group]]). This condition has been proved to be necessary if $ A $ | ||
| + | is countable. Since a subgroup of a Whitehead group is again a Whitehead group, this means that every Whitehead group is $ \aleph _ {1} $- | ||
| + | free, that is, every countable subgroup is free. Before 1973 only partial results were obtained for uncountable groups: Whitehead groups were proved to be separable and slender, and under the assumption of the [[Continuum hypothesis|continuum hypothesis]] ( $ { \mathop{\rm CH} } $), | ||
| + | they were proved to be strongly $ \aleph _ {1} $- | ||
| + | free, that is, every countable subset is contained in a countable free subgroup which is a direct summand of countable subgroups containing it (see [[#References|[a3]]] for results prior to 1973). | ||
| + | |||
| + | In 1973, S. Shelah [[#References|[a5]]] proved that it is undecidable under the axioms of Zermelo–Frankel set theory (cf. also [[Set theory|Set theory]]), ZFC, whether every Whitehead group of cardinality $ \aleph _ {1} $ | ||
| + | is free. Specifically, he proved that this is true assuming the Gödel constructibility axiom, $ V = L $( | ||
| + | see [[Gödel constructive set|Gödel constructive set]]), but it is false assuming Martin's axiom (cf. [[Suslin hypothesis|Suslin hypothesis]]) and the negation of the continuum hypothesis ( $ { \mathop{\rm MA} } + \neg { \mathop{\rm CH} } $). | ||
| + | Later he proved that $ V = L $ | ||
| + | implies that every Whitehead group, of arbitrary cardinality, is free [[#References|[a6]]]. He also proved that the problem is undecidable even if $ { \mathop{\rm CH} } $ | ||
| + | is assumed [[#References|[a7]]] and that it is consistent with $ \neg { \mathop{\rm CH} } $ | ||
| + | that there are Whitehead groups of cardinality $ \aleph _ {1} $ | ||
| + | that are not strongly $ \aleph _ {1} $- | ||
| + | free [[#References|[a8]]]. | ||
For more information see [[#References|[a1]]], [[#References|[a4]]] or [[#References|[a2]]]. | For more information see [[#References|[a1]]], [[#References|[a4]]] or [[#References|[a2]]]. | ||
Latest revision as of 08:29, 6 June 2020
A problem attributed, to J.H.C. Whitehead, which asks for a characterization of Abelian groups $ A $
that satisfy the homological condition $ { \mathop{\rm Ext} } ( A, \mathbf Z ) = 0 $,
where $ \mathbf Z $
is the group of integers under addition (cf. also Homology). A group which satisfies this condition is called a Whitehead group. An equivalent characterization is: $ A $
is a Whitehead group if and only if for every surjective homomorphism $ \pi $
onto $ A $,
if the kernel of $ \pi $
is isomorphic to $ \mathbf Z $,
then the kernel is a direct summand of the domain of $ \pi $.
A sufficient condition for $ A $
to be a Whitehead group is that $ A $
is free (see Free Abelian group). This condition has been proved to be necessary if $ A $
is countable. Since a subgroup of a Whitehead group is again a Whitehead group, this means that every Whitehead group is $ \aleph _ {1} $-
free, that is, every countable subgroup is free. Before 1973 only partial results were obtained for uncountable groups: Whitehead groups were proved to be separable and slender, and under the assumption of the continuum hypothesis ( $ { \mathop{\rm CH} } $),
they were proved to be strongly $ \aleph _ {1} $-
free, that is, every countable subset is contained in a countable free subgroup which is a direct summand of countable subgroups containing it (see [a3] for results prior to 1973).
In 1973, S. Shelah [a5] proved that it is undecidable under the axioms of Zermelo–Frankel set theory (cf. also Set theory), ZFC, whether every Whitehead group of cardinality $ \aleph _ {1} $ is free. Specifically, he proved that this is true assuming the Gödel constructibility axiom, $ V = L $( see Gödel constructive set), but it is false assuming Martin's axiom (cf. Suslin hypothesis) and the negation of the continuum hypothesis ( $ { \mathop{\rm MA} } + \neg { \mathop{\rm CH} } $). Later he proved that $ V = L $ implies that every Whitehead group, of arbitrary cardinality, is free [a6]. He also proved that the problem is undecidable even if $ { \mathop{\rm CH} } $ is assumed [a7] and that it is consistent with $ \neg { \mathop{\rm CH} } $ that there are Whitehead groups of cardinality $ \aleph _ {1} $ that are not strongly $ \aleph _ {1} $- free [a8].
For more information see [a1], [a4] or [a2].
References
| [a1] | P.C. Eklof, "Whitehead's problem is undecidable" Amer. Math. Monthly , 83 (1976) pp. 775–788 |
| [a2] | P.C. Eklof, A.H. Mekler, "Almost free modules" , North-Holland (1990) |
| [a3] | L. Fuchs, "Infinite Abelian groups" , 2 , Acad. Press (1973) |
| [a4] | R. J. Nunke, "Whitehead's problem" , Abelian Group Theory , Lecture Notes in Mathematics , 616 , Springer (1977) pp. 240–250 |
| [a5] | S. Shelah, "Infinite abelian groups, Whitehead problem and some constructions" Israel J. Math. , 18 (1974) pp. 243–25 |
| [a6] | S. Shelah, "A compactness theorem for singular cardinals, free algebras, Whitehead problem and transversals" Israel J. Math. , 21 (1975) pp. 319–349 |
| [a7] | S. Shelah, "Whitehead groups may not be free even assuming CH, I" Israel J. Math. , 28 (1977) pp. 193–203 |
| [a8] | S. Shelah, "On uncountable abelian groups" Israel J. Math. , 32 (1979) pp. 311–330 |
| [a9] | S. Shelah, "Whitehead groups may not be free even assuming CH, II" Israel J. Math. , 35 (1980) pp. 257–285 |
Whitehead problem. Encyclopedia of Mathematics. URL: http://encyclopediaofmath.org/index.php?title=Whitehead_problem&oldid=17939