ORIGINAL_ARTICLE
On the groups satisfying the converse of Schur's theorem
A famous theorem of Schur states that for a group $G$ finiteness of $G/Z(G)$ implies the finiteness of $G'.$ The converse of Schur's theorem is an interesting problem which has been considered by some authors. Recently, Podoski and Szegedy proved the truth of the converse of Schur's theorem for capable groups. They also established an explicit bound for the index of the center of such groups. This paper is devoted to determine some families of groups among non-capable groups which satisfy the converse of Schur's theorem and at the same time admit the Podoski and Szegedy's bound as the upper bound for the index of their centers.
http://ijgt.ui.ac.ir/article_1485_97332f3127ba88174f99b39be512bb8a.pdf
2012-12-01T11:23:20
2019-01-18T11:23:20
1
7
10.22108/ijgt.2012.1485
Capable group
n-isoclinism
Extra special p-group
Schur's theorem
Azam
Kaheni
azam.kaheni@stu-mail.um.ac.ir
true
1
Department of Pure Mathematics, Ferdowsi University of Mashhad, P. O. Box 1159-91775, Mashhad, Iran
Department of Pure Mathematics, Ferdowsi University of Mashhad, P. O. Box 1159-91775, Mashhad, Iran
Department of Pure Mathematics, Ferdowsi University of Mashhad, P. O. Box 1159-91775, Mashhad, Iran
AUTHOR
Rasoul
Hatamian
hatamianr@yahoo.com
true
2
Department of Pure Mathematics, Ferdowsi University of Mashhad, P. O. Box 1159-91775, Mashhad, Iran
Department of Pure Mathematics, Ferdowsi University of Mashhad, P. O. Box 1159-91775, Mashhad, Iran
Department of Pure Mathematics, Ferdowsi University of Mashhad, P. O. Box 1159-91775, Mashhad, Iran
AUTHOR
Saeed
Kayvanfar
skayvanf@yahoo.com
true
3
Department of Pure Mathematics, Ferdowsi University of Mashhad, P. O. Box 1159-91775, Mashhad, Iran
Department of Pure Mathematics, Ferdowsi University of Mashhad, P. O. Box 1159-91775, Mashhad, Iran
Department of Pure Mathematics, Ferdowsi University of Mashhad, P. O. Box 1159-91775, Mashhad, Iran
LEAD_AUTHOR
ORIGINAL_ARTICLE
CH-groups which are finite $p$-groups
In their paper "Finite groups whose noncentral commuting elements have centralizers of equal size", S. Dolfi, M. Herzog and E. Jabara classify the groups in question- which they call $ CH$-groups- up to finite $p$-groups. Our goal is to investigate the finite $p$-groups in the class. The chief result is that a finite $p$-group that is a $ CH$-group either has an abelian maximal subgroup or is of class at most $p+1$. Detailed descriptions, in some cases characterisations up to isoclinism, are given.
http://ijgt.ui.ac.ir/article_1509_028ff27c245e1f41ebc5c1a1b4f12e07.pdf
2012-12-01T11:23:20
2019-01-18T11:23:20
9
23
10.22108/ijgt.2012.1509
Finite-$p$-groups
AC-groups
conjugate rank
Bettina
Wilkens
wilkensb@mopipi.ub.bw
true
1
Lecturer at University of Botswana
Lecturer at University of Botswana
Lecturer at University of Botswana
LEAD_AUTHOR
ORIGINAL_ARTICLE
Finite simple groups with number of zeros slightly greater than the number of nonlinear irreducible characters
The aim of this paper is to classify the finite simple groups with the number of zeros at most seven greater than the number of nonlinear irreducible characters in the character tables. We find that they are exactly A$_{5}$, L$_{2}(7)$ and A$_{6}$.
http://ijgt.ui.ac.ir/article_1518_8d0839410be2400287196a5047b6c37c.pdf
2012-12-01T11:23:20
2019-01-18T11:23:20
25
32
10.22108/ijgt.2012.1518
Finite groups
characters
zeros of characters
Guangju
Zeng
weiwei@suse.edu.cn
true
1
the Chinese Mathematical Society
the Chinese Mathematical Society
the Chinese Mathematical Society
LEAD_AUTHOR
ORIGINAL_ARTICLE
Units in $\mathbb{Z}_2(C_2\times D_\infty)$
In this paper we consider the group algebra $R(C_2\times D_\infty)$. It is shown that $R(C_2\times D_\infty)$ can be represented by a $4\times 4$ block circulant matrix. It is also shown that $\mathcal{U}(\mathbb{Z}_2(C_2\times D_\infty))$ is infinitely generated.
http://ijgt.ui.ac.ir/article_1589_be4c70f82fd30aaa780db17dff9e42fc.pdf
2012-12-01T11:23:20
2019-01-18T11:23:20
33
41
10.22108/ijgt.2012.1589
Unit Group
infinite dihedral group
Circulant Matrices
R
Sharma
rksharma@maths.iitd.ac.in
true
1
Indian Institute of Technology Delhi
Indian Institute of Technology Delhi
Indian Institute of Technology Delhi
LEAD_AUTHOR
Pooja
Yadav
iitd.pooja@gmail.com
true
2
Kamla Nehru College,
University of Delhi, Delhi
Kamla Nehru College,
University of Delhi, Delhi
Kamla Nehru College,
University of Delhi, Delhi
AUTHOR
Kanchan
Joshi
kanchan.joshi@gmail.com
true
3
Department of Mathematics,
University of Delhi, Delhi
Department of Mathematics,
University of Delhi, Delhi
Department of Mathematics,
University of Delhi, Delhi
AUTHOR
ORIGINAL_ARTICLE
Fischer matrices of Dempwolff group $2^{5}{^{\cdot}}GL(5,2)$
In [U. Dempwolff, On extensions of elementary abelian groups of order $2^{5}$ by $GL(5,2)$, Rend. Sem. Mat. Univ. Padova, 48 (1972) 359 - 364.] Dempwolff proved the existence of a group of the form $2^{5}{^{\cdot}}GL(5,2)$ (a non split extension of the elementary abelian group $2^{5}$ by the general linear group $GL(5,2)$). This group is the second largest maximal subgroup of the sporadic Thompson simple group $\mathrm{Th}.$ In this paper we calculate the Fischer matrices of Dempwolff group $\overline{G} = 2^{5}{^{\cdot}}GL(5,2).$ The theory of projective characters is involved and we have computed the Schur multiplier together with a projective character table of an inertia factor group. The full character table of $\overline{G}$ is then can be calculated easily.
http://ijgt.ui.ac.ir/article_1590_e7bcdc949b15b34554b46d8c59cfc1ce.pdf
2012-12-01T11:23:20
2019-01-18T11:23:20
43
63
10.22108/ijgt.2012.1590
Group extensions
Dempwolff group
character table
Clifford Theory
inertia groups
Fischer matrices
Schur multiplier
projective characters
covering group
Ayoub
Basheer
ayoubbasheer@gmail.com
true
1
Universities of KwaZulu-Natal and Khartoum
Universities of KwaZulu-Natal and Khartoum
Universities of KwaZulu-Natal and Khartoum
LEAD_AUTHOR
Jamshid
Moori
jamshid.moori@nwu.ac.za
true
2
North-West University
North-West University
North-West University
AUTHOR
ORIGINAL_ARTICLE
On Graham Higman's famous PORC paper
We investigate Graham Higman's paper Enumerating $p$-groups, II, in which he formulated his famous PORC conjecture. We are able to simplify some of the theory. In particular, Higman's paper contains five pages of homological algebra which he uses in his proof that the number of solutions in a finite field to a finite set of monomial equations is PORC. It turns out that the homological algebra is just razzle dazzle, and can all be replaced by the single observation that if you write the equations as the rows of a matrix then the number of solutions is the product of the elementary divisors in the Smith normal form of the matrix. We obtain the PORC formulae for the number of $r$-generator groups of $p$ -class two for $r\leq 6$. In addition, we obtain the PORC formula for the number of $p$-class two groups of order $p^{8}$.
http://ijgt.ui.ac.ir/article_1591_6206fc955e4cba86c276b42fd3c4770f.pdf
2012-12-01T11:23:20
2019-01-18T11:23:20
65
79
10.22108/ijgt.2012.1591
Enumerating p-groups
PORC conjecture
Graham Higman
Michael
Vaughan-Lee
michael.vaughan-lee@chch.ox.ac.uk
true
1
Oxford University
Mathematical Institute
Oxford University
Mathematical Institute
Oxford University
Mathematical Institute
LEAD_AUTHOR