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1.
Pavel Shumyatsky 《Monatshefte für Mathematik》2007,152(2):169-175
The following theorem is proved. Let n be a positive integer and q a power of a prime p. There exists a number m = m(n, q) depending only on n and q such that if G is any residually finite group satisfying the identity ([x
1,n
y
1] ⋯ [x
m,n
y
m
])q ≡ 1, then the verbal subgroup of G corresponding to the nth Engel word is locally finite. 相似文献
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Pavel Shumyatsky 《Israel Journal of Mathematics》1994,87(1-3):111-116
Letp be a prime,G a periodic solvablep′-group acted on by an elementary groupV of orderp
2. We show that ifC
G(v) is abelian for eachv ∈V
# thenG has nilpotent derived group, and ifp=2 andC
G(v) is nilpotent for eachv ∈V
# thenG is metanilpotent. Earlier results of this kind were known only for finite groups. 相似文献
6.
Let
$$w = w(x_1, \ldots , x_n)$$
be a non-trivial word of n-variables. The word map on a group G that corresponds to w is the map
$$\widetilde{w}: G^n\rightarrow G$$
where
$$\widetilde{w}((g_1, \ldots , g_n)) := w(g_1, \ldots , g_n)$$
for every sequence
$$(g_1, \ldots , g_n)$$
. Let
$$\mathcal G$$
be a simple and simply connected group which is defined and split over an infinite field K and let
$$G =\mathcal G(K)$$
. For the case when
$$w = w_1w_2 w_3 w_4$$
and
$$w_1, w_2, w_3, w_4$$
are non-trivial words with independent variables, it has been proved by Hui et al. (Israel J Math 210:81–100, 2015) that
$$G{\setminus } Z(G) \subset {{\text { Im}}}\,\widetilde{w}$$
where Z(G) is the center of the group G and
$${{\text { Im}}}\, {\widetilde{w}}$$
is the image of the word map
$$\widetilde{w}$$
. For the case when
$$G = {{\text {SL}}}_n(K)$$
and
$$n \ge 3$$
, in the same paper of Hui et al.
(2015) it was shown that the inclusion
$$G{\setminus } Z(G)\subset {{\text { Im}}}\,\widetilde{w}$$
holds for a product
$$w = w_1w_2 w_3$$
of any three non-trivial words
$$ w_1, w_2, w_3$$
with independent variables. Here we extent the latter result for every simple and simply connected group which is defined and split over an infinite field K except the groups of types
$$B_2, G_2$$
. 相似文献
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The following theorem is proved. For any positive integers n and k there exists a number s = s(n, k) depending only on n and k such that the class of all groups G satisfying the identity
^n 1{\left(\left[x_1, {}_ky_1\right] \cdots \left[x_s, {}_ky_s\right]\right)^n \equiv 1} and having the verbal subgroup corresponding to the kth Engel word locally finite is a variety. 相似文献
9.
Let $G$ be a locally finite group which contains a non-cyclic subgroup $V$ of order four such that $C_{G}\left( V\right) $ is finite and $C_{G}\left( \phi \right)$ has finite exponent for some $\phi \in V$ . We show that $[G,\phi ]^{\prime }$ has finite exponent. This enables us to deduce that $G$ has a normal series $1\le G_1\le G_2\le G_3\le G$ such that $G_1$ and $G/G_2$ have finite exponents while $G_2/G_1$ is abelian. Moreover $G_3$ is hyperabelian and has finite index in $G$ . 相似文献
10.
It is proved that if a (?/p ?)-graded Lie algebra L, where p is a prime, has exactly d nontrivial grading components and dim L 0 = m, then L has a nilpotent ideal of d-bounded nilpotency class and of finite (m,d)-bounded codimension. As a consequence, Jacobson's theorem on constant-free nilpotent Lie algebras of derivations is generalized to the almost constant-free case. Another application is for Lie algebras with almost fixed-point-free automorphisms. 相似文献