The errata of the book is listed here. I appreciate you if you could send any errors to us by e-mail.
Page 29 Eq. (2,27)
2H_AB -> H_AB
Page 31 statement after Eq. (2.33)
km/s -> m/s
Page 49 Question [2,6]
Eq.(2,16) -> Eq.(2,15)
Eq.(2,14) -> Eq.(2,13)
Page 60 Eq. (3,11)
U^(i)_q' and u_i in the superscript.
Move from superscript to the normal position.
A correct Latex form is
\begin{equation}
{\bf u}_i = \frac{1}{\sqrt{N_{\Omega}}} \sum_{\bf k'}
e^{-i({\bf k'}\cdot{\bf R_i} - \omega t) } {\bf u}_{\bf k'}^{(i)},\\
\hspace{3mm}{\rm or}\hspace{3mm}
{\bf u}_{\bf k}^{(i)} = \frac{1}{\sqrt{N_{\Omega}}} \sum_{\bf R_i}
e^{i({\bf k}\cdot{\bf R_i} - \omega t) }
{\bf u}_i,
\label{eq:uiuk}
\end{equation}
Page 81 Eq. (4.11)
The first line
sin omega_0 t -> sin omega_i t
Page 83 Eq. (4.14)
Gamma_q should be moved from denominator to numerator
so that the integration on omega gives I_0.
Page 84 Eq. (4.15)
The ")" in both denominator and numerator should be just after
omega_RBM. If 1/q_RBM = 0, I(omega) becomes Lorentzian.
In the LaTeX, the following is a correct formula.
\begin{equation}
I(\omega)
= I_0\frac {[1+(\omega - \omega_{\rm BWF})/q_{\rm BWF}\Gamma_{\rm BWF}]^2}
{1+[(\omega - \omega_{\rm BWF})/\Gamma_{\rm BWF}]^2}\, ,
\label{eq-BWF}
\end{equation}
Page 106 the statement after Eq. (5.15)
and the summation in Eq.(5.16)
-->
and the summation in Eq.(5.14)
Page 107 Eq. (5.17)
denominator
\hbar^2 --> \hbar
Page 181 Eq. (8,2)
\omega_G - \omega_G^0 = (\Chi_T + \Chi_V) \Delta T
= (d w / dT )_T dT + (d w / dT )_V \frac {\partial V}{\partical T} Delta T
(8,2)
Page 312 Eq. (13,8)
The last exponential for the second term of C_s is missing.
..... C_S \left[ 1 - \exp \right( .... \left) \left]
@@@@
(pointed by Dr. Casimir Daniel in 2022.6.28)