Open AccessArithmetic Subgroups and Applications
Author(s) -
Mariam Almahdi Mohammed Mull'a,
Amal Mohammed Ahmed Gaweash,
Hayat Yousuf Ismail Bakur
Publication year - 2020
Publication title -
global journal of science frontier research
Language(s) - English
Resource type - Journals
eISSN - 2249-4626
pISSN - 0975-5896
DOI - 10.34257/gjsfrfvol20is6pg1
Subject(s) - mathematics , quaternion , arithmetic , cohomology , group (periodic table) , complexification , pure mathematics , discrete group , algebra over a field , lie group , geometry , chemistry , organic chemistry
Arithmetic subgroups are an important source of discrete groups acting freely on manifolds. We need to know that there exist many torsion-free L(,ℝ) is an “arithmetic” subgroup of L(,ℝ). The other arithmetic subgroups are not as obvious, but they can be constructed by using quaternion algebras. Replacing the quaternion algebras with larger division algebras yields many arithmetic subgroups of L(,ℝ), with >2. In fact, a calculation of group cohomology shows that the only other way to construct arithmetic subgroups of L(, ℝ) is by using arithmetic groups. In this paper justifies Commensurable groups, and some definitions and examples,ℝ-forms of classical simple groups over ℂ, calculating the complexification of each classical group, Applications to manifolds. Let us start with (,ℂ). This is already a complex Lie group, but we can think of it as a real Lie group of twice the dimension. As such, it has a complexification.