Lecture 2A: Groups - PowerPoint PPT Presentation

1 / 16
About This Presentation
Title:

Lecture 2A: Groups

Description:

Review of group theory and representation. In Constitutive Equations of ... Abelian Groups: combination is commutative (reversible): Oi Oj = Oj Oi; this is ... – PowerPoint PPT presentation

Number of Views:28
Avg rating:3.0/5.0
Slides: 17
Provided by: adrol
Category:

less

Transcript and Presenter's Notes

Title: Lecture 2A: Groups


1
Lecture 2A Groups
  • Ref Kiral, E. and A. C. Eringen (1990). Review
    of group theory and representation. In
    Constitutive Equations of Nonlinear
    Electromagnetic-Elastic Crystals ,
    Springer-Verlag, New York, pp. 183-209.

2
Group Theory
  • Groups are a very useful concept for dealing with
    symmetry because they allow one to collect
    together sets of symmetry operators.
  • Group theory is a significant branch of
    mathematics, independent of symmetry.
  • The Group Property is that property of a set of
    elements in which the associative combination of
    a pair of elements is equivalent to another
    member of the group.

3
What is a Group, really?
  • A group is (non-technical) a collection of
    quantities that form a closed system in which
    they are all related to one another.
  • The closed nature of a group (set of elements)
    requires a set of rules (axioms) be written down
    that describe the relations (results of
    multiplication) between the elements of the group.

4
Group Axioms (a.k.a. the rules)
  • Definitions O ? element G ? group ?
    combination operator.
  • 1. ? Oi,Oj ?G, OiOj Ok ?G (Group Property)
  • 2. Oi(OjOk) (OiOj)Ok (Associativity)
  • 3. ? I ?G, ? Oi ?G, I Oi Oi OiI. (Unit
    Element, I)
  • 4. ? Oi-1 ?G, ? Oi ?G, Oi-1 Oi I Oi Oi-1.
    (Inverse Element, Oi-1)

5
Other Properties of Groups
  • Abelian Groups combination is commutative
    (reversible) OiOj OjOi this is not typical
    for symmetry groups because rotations do not
    commute.
  • Order of a Group this is the number of elements
    in the group, e.g. 6 for point group 6.
  • Cyclic groups all elements can be generated from
    powers of a single generating element. E.g.
    rotate by 2p/n

6
Notation
  • Crystallography operators are called n-fold axes
    (or just n on diagrams) following the
    International notation. The notation nm denotes
    the mth power of n e.g. 3 denotes rotation by
    2p/3, 32 denotes rotation by 4p/3. Subscript
    denotes the axis along which rotation occurs.
  • Schoenflies operators are denoted by Cn
  • Alternate notation Luvwn where uvw denotes the
    axis along which the symmetry element operates,
    and n denotes the axis order.

7
Multiplication Tables for Groups
  • The holosymmetric orthorhombic point group mmm

8
Other Group Properties, contd.
  • Homomorphism two groups are homomorphic is a
    unidirectional correspondence exists.
  • Relation between higher lower order groups one
    or more elements from the higher order group can
    be inserted into the multiplication table of the
    lower group and still satisfy that table.
  • Example the group of proper rotations
    represented by quaternions are homomorphic with
    same as matrices.

9
Other Group Properties, contd.
  • Isomorphism special case of homomorphism two
    groups are isomorphous if a one-to-one
    correspondence (unique mapping) exists between
    the elements of the two groups.
  • Example the group of proper rotations expressed
    as matrices is isomorphous with the group of
    Rodrigues vectors.

10
Other Group Properties, contd.
  • Subgroups if you can extract/identify a subset
    of elements within a group that also form a
    group, then that set is a subgroup.
  • Improper subgroups I and the group itself.
  • Proper subgroups subgroups other than above.
  • Example out of 23, 2 is a subgroup, as is 3.

11
Other Group Properties, contd.
  • Cosets there are left cosets and right cosets
    the right coset of a subgroup is the set of
    elements formed by taking combinations of the
    subgroup with the remaining elements, writing the
    latter on the right.For a subgroup, H, of order
    p HRk H1Rk, H2Rk, .,HpRk

12
Cosets, contd.
  • Every element is either in the subgroup or one of
    its cosets.
  • No element is in both a subgroup a coset.
  • No element in more than one coset.
  • No repeated elements.
  • Order of a subgroup is a divisor of the order of
    the group (e.g. 2 and 3 divide 23).

13
Representation
  • Elements of groups commonly represented by
    matrices.
  • Combination therefore represented by matrix
    multiplication.
  • Proper Rotations (generally sufficient for
    representing orientation) are represented by the
    (infinite) group of orthogonal rotation matrices.
  • Symmetry elements represented by unimodular
    matrices.

14
Rotation Matrices
2x 180 about x-axis
Arbitrary rotationabout x-axis
15
Table of Symmetry Groups
16
Useful Groups
  • O(3) all orthogonal matrices
  • SO(3) all proper rotations (determinant1)
  • O(432) cubic point group with proper rotations
  • O(222) orthorhombic point group
  • Cubic-orthorhombic symmetry represented by
    O(222)\g/O(432)
Write a Comment
User Comments (0)
About PowerShow.com