Polymer model 27ω^2 kak=Aak. (1.7.9)Here,Ais a matrix given by
A=ω^2
1 −1 0 0 0 ··· 0 0
−1 2 −1 0 0 ··· 0 0
0 −1 2 −1 0 ··· 0 0
···
0 0 0 0 0 ··· −1 1
, (1.7.10)
and theω^2 kandakare the eigenvalues and eigenvectors, respectively. The square roots
of the eigenvalues are frequencies that correspond to a set of special modes of the chain
known as thenormal modes. By diagonalizing the matrixA, the frequencies can be
shown to be
ω^2 k= 2ω^2[
1 −cos(
(k−1)π
N)]
. (1.7.11)
Moreover, the orthogonal matrix U whose columns are the eigenvectorsakofAdefines
a transformation from the original displacement variablesηito a new set of variables
ζivia
ζi=∑
kηkUki, (1.7.12)known asnormal mode variables. By applying this transformation to the Hamiltonian
in eqn. (1.7.4), it can be shown that the transformed Hamiltonian is given by
H=
∑N
k=1p^2 ζk
2 m+
1
2
∑N
k=1mωk^2 ζ^2 k. (1.7.13)(The easiest way to derive this result is to start with the Lagrangianin terms of
η 1 ,...,ηN,η ̇ 1 ,...,η ̇N, apply eqn. (1.7.12) to it, and then perform the Legendre transform
to obtain the Hamiltonian. Alternatively, one can directly compute the inverse of the
mass-metric tensor and substitute it directly into eqn. (1.6.10).) Ineqn. (1.7.13), the
normal modes are decoupled from each other and represent a setof independent modes
with frequenciesωk.
Note that independent ofN, there is always one normal mode, thek= 1 mode,
whose frequency isω 1 = 0. This zero-frequency mode corresponds to overall transla-
tions of the entire chain in space. In the absence of an external potential, this transla-
tional motion is free, with no associated frequency. Considering this fact, the solution
of the equations of motion for each normal mode
̈ζk+ωk^2 ζk= 0 (1.7.14)can now be solved analytically:
ζ 1 (t) =ζ 1 (0) +pζ 1 (0)
mt