Mathematical Methods for Physics and Engineering : A Comprehensive Guide

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TENSORS


another, without reference to any coordinate system) and consider the matrix


containing its components as a representation of the tensor with respect to a


particular coordinate system. Moreover, the matrixT=[Tij], containing the


components of a second-order tensor, behaves in the same way under orthogonal


transformationsT′=LTLTas a linear operator.


However, not all linear operators are second-order tensors. More specifically,

the two subscripts in a second-order tensor must refer to the same coordinate


system. In particular, this means that any linear operator that transforms a vector


into a vector in a different vector space cannot be a second-order tensor. Thus,


although the elementsLijof the transformation matrix are written with two


subscripts, they cannot be the components of a tensor since the two subscripts


each refer to a different coordinate system.


As examples of sets of quantities that are readily shown to be second-order

tensors we consider the following.


(i)The outer product of two vectors.Letuiandvi,i=1, 2 ,3, be the components

of two vectorsuandv, and consider the set of quantitiesTijdefined by


Tij=uivj. (26.20)

The setTijare called the components of the theouter productofuandv. Under


rotations the componentsTijbecome


Tij′=ui′v′j=LikukLjlvl=LikLjlukvl=LikLjlTkl, (26.21)

which shows that they do transform as the components of a second-order tensor.


Use has been made in (26.21) of the fact thatuiandviare the components of


first-order tensors.


The outer product of two vectors is often denoted, without reference to any

coordinate system, as


T=u⊗v. (26.22)

(This is not to be confused with the vector product of two vectors, which is itself


a vector and is discussed in chapter 7.) The expression (26.22) gives the basis to


which the componentsTijof the second-order tensor refer: sinceu=uieiand


v=viei, we may write the tensorTas


T=uiei⊗vjej=uivjei⊗ej=Tijei⊗ej. (26.23)

Moreover, as for the case of first-order tensors (see equation (26.10)) we note

that the quantitiesTij′are the components of thesametensorT, but referred to


a different coordinate system, i.e.


T=Tijei⊗ej=Tij′e′i⊗e′j.

These concepts can be extended to higher-order tensors.

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