Difference between revisions of "Whitehead test module"
(Importing text file) |
m (AUTOMATIC EDIT (latexlist): Replaced 37 formulas out of 38 by TEX code with an average confidence of 2.0 and a minimal confidence of 2.0.) |
||
Line 1: | Line 1: | ||
− | + | <!--This article has been texified automatically. Since there was no Nroff source code for this article, | |
+ | the semi-automatic procedure described at https://encyclopediaofmath.org/wiki/User:Maximilian_Janisch/latexlist | ||
+ | was used. | ||
+ | If the TeX and formula formatting is correct, please remove this message and the {{TEX|semi-auto}} category. | ||
− | + | Out of 38 formulas, 37 were replaced by TEX code.--> | |
− | + | {{TEX|semi-auto}}{{TEX|partial}} | |
+ | Let $R$ be an associative ring with unit and let $N$ be a (unitary right $R$-) module (cf. also [[Associative rings and algebras|Associative rings and algebras]]; [[Module|Module]]). Then $N$ is a Whitehead test module for projectivity (or a p-test module) if for each module $M$, $\operatorname { Ext } _ { R } ^ { 1 } ( M , N ) = 0$ implies $M$ is projective (cf. also [[Projective module|Projective module]]). Dually, $N$ is a Whitehead test module for injectivity (or an i-test module) if for each module $M$, $\operatorname { Ext } _ { R } ^ { 1 } ( N , M ) = 0$ implies $M$ is injective (cf. also [[Injective module|Injective module]]). So, Whitehead test modules make it possible to test for projectivity (injectivity) of a module by computing a single <img align="absmiddle" border="0" src="https://www.encyclopediaofmath.org/legacyimages/w/w120/w120140/w12014012.png"/>-group. | ||
− | + | By Baer's criterion, for any ring $R$ there is a proper class of i-test modules. Dually, for any right-perfect ring (cf. also [[Perfect ring|Perfect ring]]) there is a proper class of p-test modules. If $R$ is not right perfect, then it is consistent with ZFC (cf. [[Set theory|Set theory]]; [[Zermelo axiom|Zermelo axiom]]) that there are no p-test modules, [[#References|[a2]]], [[#References|[a8]]]. | |
+ | |||
+ | This is related to the structure of Whitehead modules ($M$ is a Whitehead module if $\operatorname { Ext } _ { R } ^ { 1 } ( M , R ) = 0$, [[#References|[a1]]]). If $R$ is a right-hereditary ring, then there is a cyclic p-test module if and only if $R$ is p-test if and only if every Whitehead module is projective. The validity of the latter for $R = \mathbf{Z}$ is the famous Whitehead problem, whose independence of ZFC was proved by S. Shelah [[#References|[a5]]], [[#References|[a6]]], and whose combinatorial equivalent was identified in [[#References|[a3]]]. If $R$ is right hereditary but not right perfect, then it is consistent with ZFC that there is a proper class of p-test modules [[#References|[a8]]]. | ||
+ | |||
+ | Let $\kappa$ be a [[Cardinal number|cardinal number]]. Then $R$ is $\kappa$-saturated if each non-projective $\leq \kappa$-generated module is an i-test module. If $R$ is $\lambda$-saturated for all cardinal numbers $\lambda$, then $R$ is called a fully saturated ring [[#References|[a7]]]. There exist various non-Artinian $n$-saturated rings for $n < \aleph_0$, but all $\aleph_{0}$-saturated rings are Artinian (cf. also [[Artinian ring|Artinian ring]]). Moreover, all right-hereditary $\aleph_{0}$-saturated rings are fully saturated, and their class coincides with the class of rings $S$, $T$, or $S \boxplus T$, where $S$ is completely reducible and $T$ is Morita equivalent (cf. [[Morita equivalence|Morita equivalence]]) to the upper triangular $( 2 \times 2 )$-matrix ring over a skew-field [[#References|[a4]]] (cf. also [[Matrix ring|Matrix ring]]; [[Ring with division|Ring with division]]; [[Division algebra|Division algebra]]) | ||
====References==== | ====References==== | ||
− | <table>< | + | <table><tr><td valign="top">[a1]</td> <td valign="top"> P.C. Eklof, A.H. Mekler, "Almost free modules: set-theoretic methods" , North-Holland (1990)</td></tr><tr><td valign="top">[a2]</td> <td valign="top"> P.C. Eklof, S. Shelah, "On Whitehead modules" ''J. Algebra'' , '''142''' (1991) pp. 492–510</td></tr><tr><td valign="top">[a3]</td> <td valign="top"> P.C. Eklof, S. Shelah, "A combinatorial principle equivalent to the existence of non-free Whitehead groups" ''Contemp. Math.'' , '''171''' (1994) pp. 79–98</td></tr><tr><td valign="top">[a4]</td> <td valign="top"> P.C. Eklof, J. Trlifaj, "How to make Ext vanish" ''preprint''</td></tr><tr><td valign="top">[a5]</td> <td valign="top"> S. Shelah, "Infinite abelian groups, Whitehead problem and some constructions" ''Israel J. Math.'' , '''18''' (1974) pp. 243–256</td></tr><tr><td valign="top">[a6]</td> <td valign="top"> S. Shelah, "A compactness theorem for singular cardinals, free algebras, Whitehead problem and transversals" ''Israel J. Math.'' , '''21''' (1975) pp. 319–349</td></tr><tr><td valign="top">[a7]</td> <td valign="top"> J. Trlifaj, "Associative rings and the Whitehead property of modules" , ''Algebra Berichte'' , '''63''' , R. Fischer (1990)</td></tr><tr><td valign="top">[a8]</td> <td valign="top"> J. Trlifaj, "Whitehead test modules" ''Trans. Amer. Math. Soc.'' , '''348''' (1996) pp. 1521–1554</td></tr></table> |
Revision as of 16:55, 1 July 2020
Let $R$ be an associative ring with unit and let $N$ be a (unitary right $R$-) module (cf. also Associative rings and algebras; Module). Then $N$ is a Whitehead test module for projectivity (or a p-test module) if for each module $M$, $\operatorname { Ext } _ { R } ^ { 1 } ( M , N ) = 0$ implies $M$ is projective (cf. also Projective module). Dually, $N$ is a Whitehead test module for injectivity (or an i-test module) if for each module $M$, $\operatorname { Ext } _ { R } ^ { 1 } ( N , M ) = 0$ implies $M$ is injective (cf. also Injective module). So, Whitehead test modules make it possible to test for projectivity (injectivity) of a module by computing a single -group.
By Baer's criterion, for any ring $R$ there is a proper class of i-test modules. Dually, for any right-perfect ring (cf. also Perfect ring) there is a proper class of p-test modules. If $R$ is not right perfect, then it is consistent with ZFC (cf. Set theory; Zermelo axiom) that there are no p-test modules, [a2], [a8].
This is related to the structure of Whitehead modules ($M$ is a Whitehead module if $\operatorname { Ext } _ { R } ^ { 1 } ( M , R ) = 0$, [a1]). If $R$ is a right-hereditary ring, then there is a cyclic p-test module if and only if $R$ is p-test if and only if every Whitehead module is projective. The validity of the latter for $R = \mathbf{Z}$ is the famous Whitehead problem, whose independence of ZFC was proved by S. Shelah [a5], [a6], and whose combinatorial equivalent was identified in [a3]. If $R$ is right hereditary but not right perfect, then it is consistent with ZFC that there is a proper class of p-test modules [a8].
Let $\kappa$ be a cardinal number. Then $R$ is $\kappa$-saturated if each non-projective $\leq \kappa$-generated module is an i-test module. If $R$ is $\lambda$-saturated for all cardinal numbers $\lambda$, then $R$ is called a fully saturated ring [a7]. There exist various non-Artinian $n$-saturated rings for $n < \aleph_0$, but all $\aleph_{0}$-saturated rings are Artinian (cf. also Artinian ring). Moreover, all right-hereditary $\aleph_{0}$-saturated rings are fully saturated, and their class coincides with the class of rings $S$, $T$, or $S \boxplus T$, where $S$ is completely reducible and $T$ is Morita equivalent (cf. Morita equivalence) to the upper triangular $( 2 \times 2 )$-matrix ring over a skew-field [a4] (cf. also Matrix ring; Ring with division; Division algebra)
References
[a1] | P.C. Eklof, A.H. Mekler, "Almost free modules: set-theoretic methods" , North-Holland (1990) |
[a2] | P.C. Eklof, S. Shelah, "On Whitehead modules" J. Algebra , 142 (1991) pp. 492–510 |
[a3] | P.C. Eklof, S. Shelah, "A combinatorial principle equivalent to the existence of non-free Whitehead groups" Contemp. Math. , 171 (1994) pp. 79–98 |
[a4] | P.C. Eklof, J. Trlifaj, "How to make Ext vanish" preprint |
[a5] | S. Shelah, "Infinite abelian groups, Whitehead problem and some constructions" Israel J. Math. , 18 (1974) pp. 243–256 |
[a6] | S. Shelah, "A compactness theorem for singular cardinals, free algebras, Whitehead problem and transversals" Israel J. Math. , 21 (1975) pp. 319–349 |
[a7] | J. Trlifaj, "Associative rings and the Whitehead property of modules" , Algebra Berichte , 63 , R. Fischer (1990) |
[a8] | J. Trlifaj, "Whitehead test modules" Trans. Amer. Math. Soc. , 348 (1996) pp. 1521–1554 |
Whitehead test module. Encyclopedia of Mathematics. URL: http://encyclopediaofmath.org/index.php?title=Whitehead_test_module&oldid=50089