~-INJECTORS
OF FINITE GROUPS
Ya. L. Fel'dman
UDC 519.44
All the groups under consideration are finite. Let ~ be a Fi...
30 downloads
737 Views
169KB Size
Report
This content was uploaded by our users and we assume good faith they have the permission to share this book. If you own the copyright to this book and it is wrongfully on our website, we offer a simple DMCA procedure to remove your content from our site. Start by pressing the button below!
Report copyright / DMCA form
~-INJECTORS
OF FINITE GROUPS
Ya. L. Fel'dman
UDC 519.44
All the groups under consideration are finite. Let ~ be a Fitting class. We will say that a group G has the C~-property if it contains ~-injectors and any two ~-injectors in G are conjugate. The basis theorem of the theory of Fitting classes (see [i]) ensures that each solvable group has the C~-property. The result of Gaseh~tz, dual to it, from the theory of formation has been extended independently in [2] and [3], where it is established that a group G has ~-projectors and any two ~-projectors in G are conjugate if the ,~-coresidual GS?, where ~O is a local formation, is solvable. Naturally the following question is posed for the Fitting class 3: also: If the quotient group G/G~ modulo the J-radical is solvable, then does the group G itself have the C~-property? For a locally defined Fitting class ~ an affirmative answer can be obtained from the fundamental theorem of [4]. However, as observed in [5], not even each subgroup-closed Fitting class is locally defined. In this article we will study the above question for the Fitting class ~., equal to the product ~ of the Fitting classes .~ and ~), where .~) = {O : G/G.~. C ~)} In particular, it is established that if a group G is such that the quotient group GIGs. is solvable and ~ ) ~ ~J~, then it has the C ~)-property. '~ The structure of the ~)-injectors is indicated. Here, and in what follows, 9~ denotes the class of nilpotent groups and J~ denotes the class of nilpotent ~-groups. See [5] for all the definitions and notation. LEMMA i.
Let G be a group, F(G)_AH_AG, and the quotient group G/H be solvable.
Then
CG(n)~_H. Proof. Let us set r = r and F(G) =F. Then r176 The lemma of [6] contains the following result: If S/~ is the product of all minimal normal subgroups of the group G/~, then C G ( S ) ~ S . Therefore, it is sufficient to prove that H ~ S . Let N/~ be a minimal normal subgroup of the group G/~. Let us assume that N~_H. Then N ~ H = O and N / ~ N H / H . But NH/H is a minimal normal subgroup of the solvable group G/H and is therefore Abelian~ Therefore N/~ is also Abelian; whence, by a well-known theorem of Gasch'utz [7], the subgroup N is nilpotent. But then N - - F ~ H , which is a contradiction. Thus, N ~ H and, since the subgroup N/~ has been chosen arbitrarily, it follows that S--H. The lemma is proved. COROLLARY i. Let G be a group, ~ be a Fitting class,and ~ J ~ , the quotient group G/G~ is solvable, then C~;(G~)~_G~.
where
~(G/G~).
If
Indeed, let F ( G ) = F = F ~ F ~ ' , where F~ is a Hall ~-subgroup of F. It is clear that F ~ G~ and, since F/F N G~-~FG?JG~92~, it follows that F.~,~F ,Q G~__G3. Thus, F~_G~ and by Lemma 1 we have C~(G~) _ G~. LEMMA 2 If the group
Let G be a group, ~ and ~ be Fitting classes, and ~ ~ J ~ , where ~ = solvable and G I~A ~ V ~ G , then
z~(G/GE~),
G/GE~ is
1) g~ -~O~; 2) the subgroup V is ~ - m a x i m a l
in G if and only if
VfG?s is ~-maximal in G/G~. H / K = (O/l()~ and (G/If)/(G/IO~ ~G/H
Proof. i) Let us set H = Oi~)and K = G l= H~. Since is a so-~-~vable group, by virtue of Corollary 1 it follows that CG/K~(H/K)~H/K. Sin~e IVy, H]-----V~H=H~=K, it follows that V~_Co(H/IO~_H. Consequently, V~__H~. The reverse inclusion is obvious. 2) Let us assume that V is an ~ - m a x i m a l subgroup of G. By the above statement we have V ~ O ~ and therefore V/G~ ~. If V/G?~~__W/G~~__G/~ and W / ~ , then W~ = 0~ implies that W ~ . Consequently, W = V and, therefore, V/G~ is ~-maximal in G/G~. Ukrainian Hydroengineering Project, Ministry of Housing and Communal Services of the Ukrainian SSR. Translated from Ukrainskii Matematicheskii Zhurnal, Vol. 32, No. 2, pp. 265-267, March-April, 1980. Original article submitted August 9, 1978.
0041-5995/80/3202-0173507.50
9 1980 Plenum Publishing Corporation
173
Conversely, let V/G~ be ~-maximal in G/G~. The equality V~ = G~ implies that F C ~ . If V ~ W ~ G and W E ~ , then W~ = 02 and W/G~6~. Hence W =V, and the lemma is proved. THEOREM i. Let G be a group and ~ and ~ be Fitting classes, ~___~, where v = ~(G/G~), and let the group G/G~ be solvable. If the group O/O 2 has the C~-property, then the group G has the C~-propert~; moreover, the subgroup V of G is an ~ - i n j e c t o r of G if and only if V/G~ is a~-injector of the group G/G~. Proof. By the condition the group G/G~ has ~-injectors; let V/G~ be one of them. We then show that the subgroup V is anX~-injector of the group G. Let N be an arbitrary subnormal subgroup of G. Then N~ = N N G~ and N/N~ ~NG~/G~. The subgroup V N N/N~ of N/N~ is isomorphic to the subgroup (VNN)G~/G~, which is obviously a ~-injector of the group NG~/G~. Consequently, V N N / N ~ is a~-injector and is, therefore, a ~ - m a x i m a l subgroup of the group N/N~. Since N ~ = G ~ N N ~ V N N and N / N ~ N G ~ / G ~ is a solvable group, it follows by Lemma 2 that V n N is an ~ - m a x i m a l subgroup in N. By the same token it is proved that the subgroup V is an ~ - i n j e c t o r of G. Conversely, let us assume that the subgroup V is a n ~ - i n j e c t o r of G. We show that is a ~-injector of the group G/G~. Let N/G~ be an arbitrary subnormal subgroup of G/G~. Then we again have N ~ = N N G ~ N N V, and by Lemma 2 we have (NNV)~ = N ~ = G~. Since N ~V, being an ~-injector in N, is ~ - m a x i m a l in N, it follows that N n V/G~ is ~-maximal in N/G~. Thus, V/G~ is a~-injector of the group G/G~.
V/G~
Let V~ and V~ be two different ~ - i n j e c t o r s of G. Then the subgroups V~/G~ and V~/G~, being~-injectors of the group G/G~, which has the C~-property, are conjugate in it. Consequently, the subgroups V~ and V~ are conjugate in the group G. The theorem is proved. We get the following corollary from the above theorem and a result of Fischer, Gasch~tz, and Hartley (see [i]). COROLLARY 2. Let G be a group and ~ and ~ be Fitting classes such that ~_____~. If the quotient group G/G~ is solvable, then G has the C~-property; moreover, a subgroup V is an ~-injector in G if and only if V/G~ is a~-injector in G/G~. Let us observe that for a solvable group G this structure of ~ - i n j e c t o r s has been obtained in [5]. LITERATURE CITED l.
2. 3. 4. 5. 6.
7.
174
B. Fischer, W. Gasch~tz, and B. Hartley, "Injectoren endlicher aufl~sbarer Gruppen," Math. Z., 102, No. 5, 337-339 (1967). E. F. Shmigirev, "On certain questions of the theory of formations," in: Finite Groups [in Russian], Nauka i Tekhnika, Minsk (1975), pp. 211-225. P. Schmid, "Lokale Formationen endlicher Gruppen," Math. Z., 137, No. i, 31-48 (1974). F. R. Schnackenberg, "Injectorsof finite groups," J. Algebra, 30, Nos. 1-3, 548-558 (1974). B. Hartley, "On Fischer's dualization of formation theory," Proc. London Math. Soc., 19, Part 2, 193-207 (1969). L. A. Shemetkov, "Outer saturation of homogeneous formations," in: All-Union Algebraic Symposium; Abstracts of Report [in Russian], Part i, Nauka i Tekhnika, Gomel (1975), p. 79. W. GaschHtz, "Uber die r endlicher Gruppen," Math. Z., 58, 160-170 (1953).