Introduction to Mathematical Physics/Groups

Definition:

A group is a set of elements ${\displaystyle G=\{g_{1},g_{2},\dots \}}$ and a composition law ${\displaystyle .}$ that assigns to any ordered pair ${\displaystyle (g_{1},g_{2})\in G}$ an element ${\displaystyle g_{1}.g_{2}}$ of ${\displaystyle G}$. The composition law ${\displaystyle .}$ is

• associative
  ${\displaystyle g_{1}.(g_{2}.g_{3})=(g_{1}.g_{2}).g_{3}}$
• has a unit element ${\displaystyle e}$ :
  ${\displaystyle g.e=e.g=e}$
• for each ${\displaystyle g}$ of ${\displaystyle G}$, there exists an element ${\displaystyle g^{-1}}$ of ${\displaystyle G}$ such that:
  ${\displaystyle g.g^{-1}=g^{-1}.g=e}$

Definition:

The order of a group is the number of elements of ${\displaystyle G}$.

Definition:

A representation of a group ${\displaystyle G}$ in a vectorial space ${\displaystyle V}$ on ${\displaystyle K=R}$ or ${\displaystyle K=C}$ is an endomorphism ${\displaystyle \Pi }$ from ${\displaystyle G}$ into the group ${\displaystyle GL(V)}$\footnote{${\displaystyle GL(V)}$ is the space of the linear applications from ${\displaystyle V}$ into ${\displaystyle V}$. It is a group with respect to the function composition law.} {\it i.e }a mapping

${\displaystyle {\begin{array}{llll}\Pi :&G&\longrightarrow &GL(V)\\&g&\longrightarrow &\Pi (g)\end{array}}}$

with

${\displaystyle \Pi (g_{1}.g_{2})=\Pi (g_{1}).\Pi (g_{2})}$

Definition:

Let ${\displaystyle (V,\Pi )}$ be a representation of ${\displaystyle G}$. A vectorial subspace ${\displaystyle W}$ of ${\displaystyle V}$ is called stable by ${\displaystyle \Pi }$ if:

${\displaystyle \forall g\in G,\Pi (g).W\subset V.}$

One then obtains a representation of ${\displaystyle G}$ in ${\displaystyle W}$ called subrepresentation of ${\displaystyle \Pi }$.

Definition:

A representation ${\displaystyle (V,\Pi )}$ of a group ${\displaystyle G}$ is called irreducible if it admits no subrepresentation other than ${\displaystyle 0}$ and itself.

Example:

Let ${\displaystyle G}$ be a group of transformations ${\displaystyle {\mathcal {r}}}$ of space ${\displaystyle R^{3}}$. A representation ${\displaystyle \Pi _{1}}$ of ${\displaystyle G}$ in ${\displaystyle V=R^{3}}$ is simply defined by:

${\displaystyle {\begin{array}{llll}\Pi _{1}({\mathcal {r}}):&R^{3}&\longrightarrow &R^{3}\\&{\vec {x}}&\longrightarrow &{\vec {x}}'={\mathcal {R}}({\vec {x}})\end{array}}}$

To each element ${\displaystyle {\mathcal {r}}}$ of ${\displaystyle G}$, a mapping ${\displaystyle {\mathcal {R}}}$ of ${\displaystyle R^{3}}$ is associated. This mapping can be defined by a matrix ${\displaystyle M}$ called representation matrix of symmetry operator ${\displaystyle {\mathcal {r}}}$.

Example:

Let us consider molecule ${\displaystyle NH_{3}}$ as a solid of symmetry ${\displaystyle C_{3}}$. The various symmetry operations that characterizes this group are:

• three reflexions ${\displaystyle \sigma _{1}}$,${\displaystyle \sigma _{2}}$, and ${\displaystyle \sigma _{3}}$.
• two rotations around the ${\displaystyle C_{3}}$ axis, of angle ${\displaystyle {\frac {2\pi }{3}}}$ and ${\displaystyle {\frac {4\pi }{3}}}$ noted ${\displaystyle C_{3}^{1}}$ and ${\displaystyle C_{3}^{2}}$.
• rotation of angle ${\displaystyle {\frac {6\pi }{3}}}$ is the identity and is noted ${\displaystyle E}$.

In a any basis of ${\displaystyle R^{3}}$, representation matrices of group symmetry operators are in general not block diagonal.

The tridimensional space can be shared into two invariant subspaces: a one-dimensional space ${\displaystyle E_{1}}$ spanned by vector of the ${\displaystyle C_{3}}$ axis, and a plane ${\displaystyle E_{3}}$ perpendicular to this vector. In chemistry books, representation on ${\displaystyle E_{1}}$ is called ${\displaystyle A}$ and representation on ${\displaystyle E_{2}}$ is called ${\displaystyle E}$. They are both irreducible.

Remark:

For the study of the vibrations of a molecule, instead of considering the Euclidian space ${\displaystyle R^{3}}$ as state space, the space of the ${\displaystyle q_{i}}$'s where the ${\displaystyle q_{i}}$'s are the degree of freedom of the system has to be considered. The diagonalization of the coupling matrix problem can be tackled using symmetry considerations. Indeed, a vibratory system is invariant by symmetry ${\displaystyle G}$, implies that its energy is invariant by ${\displaystyle G}$:

${\displaystyle \forall g\in G,\forall x\in V,<M^{+}(g)x|KM(g)x>=<x|Kx>}$

Matrices ${\displaystyle M(g)}$ being orthonormal, kinetic energy is also invariant.

Theorem:

If operator ${\displaystyle A}$ is invariant by ${\displaystyle R}$, that is ${\displaystyle \rho _{R}A=A}$ or ${\displaystyle RAR^{-1}=A}$, the if ${\displaystyle \phi }$ is eigenvector of ${\displaystyle A}$, ${\displaystyle R\phi }$ is also eigenvector of ${\displaystyle A}$.

Proof:

It is sufficient to evaluate the action of ${\displaystyle A}$ on ${\displaystyle R\phi }$ to prove this theorem.

Example:

Consider the group ${\displaystyle G}$ introduced at example exampgroupR. A representation ${\displaystyle \Pi _{2}}$ of ${\displaystyle G}$ in the space ${\displaystyle L^{2}}$ of summable squared can be defined by:

${\displaystyle {\begin{array}{llll}\Pi _{2}({\mathcal {r}}):&L^{2}(R^{3})&\longrightarrow &L^{2}(R^{3})\\&f(x)&\longrightarrow &Rf(x)=f({\mathcal {R}}^{-1}({\vec {x}}))\end{array}}}$

where ${\displaystyle {\mathcal {R}}=\Pi _{1}({\mathcal {r}})}$ is the matrix representation of transformation ${\displaystyle {\mathcal {r}}}$, element of ${\displaystyle G}$. If ${\displaystyle \phi _{i}}$ is a basis of ${\displaystyle L^{2}(R^{3})}$, then we have ${\displaystyle R\phi _{i}=D_{ki}\phi _{i}}$.

Example:

Consider the group ${\displaystyle G}$ introduced at example exampgroupR. A representation ${\displaystyle \Pi _{3}}$ of ${\displaystyle G}$ in the space of linear operators of ${\displaystyle L^{2}}$ can be defined by:

${\displaystyle {\begin{array}{llll}\Pi _{3}({\mathcal {r}}):&{\mathcal {L}}(L^{2}(R^{3}))&\longrightarrow &{\mathcal {L}}(L^{2}(R^{3}))\\&A&\longrightarrow &\rho _{A}=RAR^{-1}\end{array}}}$

where ${\displaystyle R=\Pi _{2}({\mathcal {r}})}$ is the matrix representation, defined at prevoius example, of transformation ${\displaystyle {\mathcal {r}}}$, element of ${\displaystyle G}$ and ${\displaystyle A}$ is the matrix defining the operator

Definition:

A scalar operator ${\displaystyle S}$ is invariant by rotation:

${\displaystyle RSR^{-1}=S}$

Definition:

A vectorial operator ${\displaystyle V}$ is a set of three operators ${\displaystyle V_{m}}$, ${\displaystyle m=-1,0,1}$, (the components of ${\displaystyle V}$ in spherical coordinates) that verify the commutation relations:

${\displaystyle [X_{i},V_{m}]=\epsilon _{imk}V_{k}}$

Definition:

A tensorial operator ${\displaystyle T}$ of components ${\displaystyle T_{m}^{j}}$ is an operator whose transformation by rotation is given by:

${\displaystyle RT_{m}^{j}R^{-1}=D_{m'm}^{j}(R)T_{m'}^{j}}$

where ${\displaystyle D_{m'm}^{j}(R)}$ is the restriction of rotation ${\displaystyle R}$ to space spanned by vectors ${\displaystyle |jm>}$.

${\displaystyle D_{m'm}^{j}(R)=<jm'|R|jm>}$

Example: piezoelectricity. As seen at section secpiezo, there exists for piezoelectric materials a relation between the deformation tensor ${\displaystyle e_{ij}}$ and the electric field ${\displaystyle h_{k}}$

${\displaystyle e_{ij}=a_{ijk}h_{k}}$

${\displaystyle a_{ijk}}$ is called the piezoelectric tensor. Let us show how previous considerations allow to obtain following result:

Proof:

Let us consider the operation ${\displaystyle R}$ symmetry with respect to the centre, then

${\displaystyle R(x_{i}x_{j}x_{k})=(-1)^{3}x_{i}x_{j}x_{k}.}$

The symmetry implies

${\displaystyle Ra_{ijk}=a_{ijk}}$

so that

${\displaystyle a_{ijk}=-a_{ijk}}$

which proves the theorem.