Introduction to Mathematical Physics/Dual of a vectorial space

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When ${\displaystyle E}$ has a finite dimension, then ${\displaystyle E^{*}}$ has also a finite dimension and its dimension is equal to the dimension of ${\displaystyle E}$. If ${\displaystyle E}$ has an infinite dimension, ${\displaystyle E^{*}}$ has also an infinite dimension but the two spaces are not isomorphic.

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In this appendix, we introduce the fundamental notion of tensor\index{tensor} in physics. More information can be found in ([#References|references]) for instance. Let ${\displaystyle E}$ be a finite dimension vectorial space. Let ${\displaystyle e_i}$ be a basis of ${\displaystyle E}$. A vector ${\displaystyle X}$ of ${\displaystyle E}$ can be referenced by its components ${\displaystyle x^i}$ is the basis ${\displaystyle e_i}$: Template:IMP/eq In this chapter the repeated index convention (or {\bf Einstein summing convention}) will be used. It consists in considering that a product of two quantities with the same index correspond to a sum over this index. For instance: Template:IMP/eq or Template:IMP/eq To the vectorial space ${\displaystyle E}$ corresponds a space ${\displaystyle E^{*}}$ called the dual of ${\displaystyle E}$. A element of ${\displaystyle E^{*}}$ is a linear form on ${\displaystyle E}$: it is a linear mapping ${\displaystyle p}$ that maps any vector ${\displaystyle Y}$ of ${\displaystyle E}$ to a real. ${\displaystyle p}$ is defined by a set of number ${\displaystyle x_i}$ because the most general form of a linear form on ${\displaystyle E}$ is: Template:IMP/eq A basis ${\displaystyle e^i}$ of ${\displaystyle E^{*}}$ can be defined by the following linear form Template:IMP/eq where ${\displaystyle {\delta }_i^j}$ is one if ${\displaystyle i=j}$ and zero if not. Thus to each vector ${\displaystyle X}$ of ${\displaystyle E}$ of components ${\displaystyle x^i}$ can be associated a dual vector in ${\displaystyle E^{*}}$ of components ${\displaystyle x_i}$: Template:IMP/eq The quantity Template:IMP/eq is an invariant. It is independent on the basis chosen. On another hand, the expression of the components of vector ${\displaystyle X}$ depend on the basis chosen. If ${\displaystyle {\omega }_k^i}$ defines a transformation that maps basis ${\displaystyle e_i}$ to another basis ${\displaystyle e{\text{'}}_i}$ Template:IMP/label Template:IMP/eq we have the following relation between components ${\displaystyle x_i}$ of ${\displaystyle X}$ in ${\displaystyle e_i}$ and ${\displaystyle x{\text{'}}_i}$ of ${\displaystyle X}$ in ${\displaystyle e{\text{'}}_i}$: Template:IMP/label Template:IMP/eq This comes from the identification of Template:IMP/eq and Template:IMP/eq Equations eqcov and eqcontra define two types of variables: covariant variables that are transformed like the vector basis. ${\displaystyle x_i}$ are such variables. Contravariant variables that are transformed like the components of a vector on this basis. Using a physicist vocabulary ${\displaystyle x_i}$ is called a covariant vector and ${\displaystyle x^i}$ a contravariant vector.

Let ${\displaystyle x_i}$ and ${\displaystyle y_j}$ two vectors of two vectorial spaces ${\displaystyle E_1}$ and ${\displaystyle E_2}$. The tensorial product space ${\displaystyle E_1\otimes E_2}$ is the vectorial space such that there exist a unique isomorphism between the space of the bilinear forms of ${\displaystyle E_1\times E_2}$ and the linear forms of ${\displaystyle E_1\otimes E_2}$. A bilinear form of ${\displaystyle E_1\times E_2}$ is: Template:IMP/eq It can be considered as a linear form of ${\displaystyle E_1\otimes E_2}$ using application ${\displaystyle \otimes }$ from ${\displaystyle E_1\times E_2}$ to ${\displaystyle E_1\otimes E_2}$ that is linear and distributive with respect to ${\displaystyle +}$. If ${\displaystyle e_i}$ is a basis of ${\displaystyle E_1}$ and ${\displaystyle f_j}$ a basis of ${\displaystyle E_2}$, then Template:IMP/eq ${\displaystyle e_i\otimes e_j}$ is a basis of ${\displaystyle E_1\otimes E_2}$. Thus tensor ${\displaystyle x_i{y}_j=T_{ij}}$ is an element of ${\displaystyle E_1\otimes E_2}$. A second order covariant tensor is thus an element of ${\displaystyle E^{*}\otimes E^{*}}$. In a change of basis, its components ${\displaystyle aij}$ are transformed according the following relation: Template:IMP/eq Now we can define a tensor on any rank of any variance. For instance a tensor of third order two times covariant and one time contravariant is an element ${\displaystyle a}$ of ${\displaystyle E^{*}\otimes E^{*}\otimes E}$ and noted ${\displaystyle a_{ij}^k}$.

A second order tensor is called symmetric if ${\displaystyle a_{ij}=a_{ji}}$. It is called antisymmetric is ${\displaystyle a_{ij}=-a_{ji}}$.

Pseudo tensors are transformed slightly differently from ordinary tensors. For instance a second order covariant pseudo tensor is transformed according to: Template:IMP/eq where ${\displaystyle det(\omega )}$ is the determinant of transformation ${\displaystyle \omega }$.

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Let us introduce two particular tensors.

• The Kronecker symbol ${\displaystyle {\delta }_{ij}}$ is defined by: Template:IMP/eq It is the only second order tensor invariant in ${\displaystyle R^3}$ by rotations.
• The signature of permutations tensor ${\displaystyle e_{ijk}}$ is defined by:

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It is the only pseudo tensor of rank 3 invariant by rotations in ${\displaystyle R^3}$. It verifies the equality: Template:IMP/eq

Let us introduce two tensor operations: scalar product, vectorial product.

• Scalar product ${\displaystyle a.b}$ is the contraction of vectors ${\displaystyle a}$ and ${\displaystyle b}$ : Template:IMP/eq
• vectorial product of two vectors ${\displaystyle a}$ and ${\displaystyle b}$ is: Template:IMP/eq

From those definitions, following formulas can be showed:

Here is useful formula: Template:IMP/eq

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Green's theorem allows one to transform a volume calculation integral into a surface calculation integral. Template:IMP/thm Here are some important Green's formulas obtained by applying Green's theorem: Template:IMP/eq Template:IMP/eq Template:IMP/eq

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