Non-relativistic kinematics
References
- TRIUMF Relativistic Handbook, Section V Relativistic Kinematics
Formulae for Non-relativistic Kinematics
Two Body Kinematics Formulae
Adopt units where $c=1$. In the Laboratory System (Center of Mass System), mass, momentum, kinetic energy, and velocity of the $i$-th particle are $m_i$, $\boldsymbol{p}_i$, and $T_i$, and $\boldsymbol{v}_i$ ($m_i^*$, $\boldsymbol{p}_i^*$, $T_i^*$, and $\boldsymbol{v}_i^*$), respectively.
In the following, the quantities $\delta_{ij}$ are defined by \begin{align} \delta_{ij} = |\boldsymbol{v}_i|/|\boldsymbol{v}_j|, \end{align} where the subscripts refer to the particles. In the case of elastic scattering, $|\boldsymbol{p}_3^{*}| = |\boldsymbol{p}_1^{*}|$ as below. In addition, $\boldsymbol{p}_1^* = m_1\boldsymbol{v}_1^* = \frac{m_2}{m_1+m_2}\boldsymbol{p}_1$ and $\boldsymbol{v}_2^* = \boldsymbol{v}_{\rm cm} = \frac{\boldsymbol{p}_1} {m_1+m_2}$. From these formula,
\begin{align} \delta_{23}^* = \delta_{21}^* = |\boldsymbol{v}_2^*|/|\boldsymbol{v}_1^*| = m_1/m_2. \end{align}
| Quantity | General Formula | Elastic Scattering | N-N Scattering (equal mass) |
| 1. Total c.m. energy (invariant mass) | \begin{align} W &= m_1 + m_2\\ &= m_3 + m_4? \end{align} | Same as the General formula | \begin{align} W= 2m_\mathrm{N}? \end{align} |
| 2. c.m. momentum before the interaction | \begin{align} \boldsymbol{p}_1^* &= \frac{m_2}{m_1+m_2}\boldsymbol{p}_1\\ &= \frac{m_1m_2}{m_1+m_2}\boldsymbol{v}_1 \end{align} | Same as the General formula | \begin{align} \boldsymbol{p}_1' = \frac{\boldsymbol{p}_1}{2} \end{align} |
| 3. c.m. momentum after the interaction | \begin{align} \boldsymbol{p}_3^* &= \frac{m_4}{m_3+m_4}\boldsymbol{p}_3\\ &= \frac{m_3m_4}{m_3+m_4}\boldsymbol{v}_3 \end{align} | \begin{align} |\boldsymbol{p}_3^{*}| = |\boldsymbol{p}_1^{*}| \end{align} | \begin{align} |\boldsymbol{p}_3'| = |\boldsymbol{p}_1'| = \frac{\boldsymbol{p}_1}{2} \end{align} |
| 4. Velocity of the c.m. | \begin{align} \boldsymbol{v}_2^* = \boldsymbol{v}_{\rm cm} = \frac{\boldsymbol{p}_1}{m_1+m_2} \end{align} | Same as the General formula | Same as the General formula |
| 5. $\gamma$ of the c.m. | \begin{align} \gamma_2^* = \gamma_\mathrm{cm}^* \approx 1? \end{align} | Same as the General formula | Same as the General formula |
| 6. Maximum lab scattering angle | \begin{align} \tan\theta_{3\mathrm{max}} = \frac{1}{\sqrt{\delta_{23}^{*2}-1}}\\ \mathrm{For\ \ } \delta_{23}^* \ge 1\\ \mathrm{otherwise\ } \theta_{3\mathrm{max}} = 180^\circ \end{align} | Same as the General formula | \begin{align} \theta_{3\mathrm{max}} = 90^\circ \end{align} |
| 7. c.m. to lab angle ($\theta_{\rm cm} \rightarrow \theta_{\rm lab}$) | \begin{align} \cos\theta_3 = \frac{\delta_{23}^*+\cos\theta_3^*}{\sqrt{\sin^2\theta_3^*+\left(\delta_{23}^*+\cos\theta_3^*\right)^2}} \end{align} | \begin{align} \tan\theta_3 &= \frac{\sin\theta_3^*}{\delta_{21}^*+\cos\theta_3^*}\\ \tan\theta_4 &= \cot\frac{\theta_3^*}{2} \end{align} | \begin{align} \tan\theta_3 = \frac{\sin\theta_3^*}{1+\cos\theta_3^*}\\ \end{align} |
| 8. lab to c.m. angle transformation ($\theta_\mathrm{lab} \rightarrow \theta_\mathrm{cm}$) | \begin{align} \cos\theta_3^*=-\frac{\delta_{23}^*\tan^2\theta_3}{\tan^2\theta_3+1}\pm\sqrt{\left(\frac{\delta_{23}^*\tan^2\theta_3}{\tan^2\theta_3+1}\right)^2-\frac{\delta_{23}^{*2}\tan^2\theta_3-1}{\tan^2\theta_3+1}} \end{align} Another solution (not written in the document) \begin{align} \tan\theta_{\rm cm} = \frac{\sin\theta_{\rm lab}}{\left(\cos\theta_{\rm lab}-v_{\rm cm}/|\boldsymbol{v}_3|\right)} \end{align} | ||
| 9. Solid angle transformation (Jacobian) | \begin{align} \frac{d\Omega_3}{d\Omega_3^*} &= \frac{1+\delta_{23}^*\cos\theta_3^*}{\left[\sin^2\theta_3^*+\left(\delta_{23}^*+\cos\theta_3^*\right)^2\right]^{3/2}}\\ \frac{d\Omega_3}{d\Omega_3^*} &= \frac{\sin^3\theta_3}{\sin^3\theta_3^*}(1+\delta_{23}^*\cos\theta_3^*) \end{align} | \begin{align} \frac{d\Omega_3}{d\Omega_3^*} = \frac{1}{2^{3/2}\sqrt{1+\cos\theta_3^*}} \end{align} | |
| 10. Relations between the $\gamma$ factors N.B. $k_{12}=m_1/m_2$ | Undefined? | Undefined? | Undefined? |
| 11. Lab quantity relations | \begin{align} 2|\boldsymbol{p}_1||\boldsymbol{p}_3|\cos\theta_3 &= \boldsymbol{p}_1^2 + \boldsymbol{p}_3^2 - \boldsymbol{p}_4^2\\ 2|\boldsymbol{p}_3||\boldsymbol{p}_4|\cos(\theta_3+\theta_4) &= \boldsymbol{p}_1^2 - \boldsymbol{p}_3^2 - \boldsymbol{p}_4^2 \end{align} | \begin{align} |\boldsymbol{p}_3||\boldsymbol{p}_4|\cos(\theta_3+\theta_4) &= 0\\ \theta_3+\theta_4 &= 90^\circ \end{align} | |
| 12. Maximum K.E. transfer to a stationary particle | \begin{align} T_\mathrm{max}=\frac{\left[\sqrt{m_1m_4}\pm\sqrt{m_3(m_3+m_4-m_1)}\right]^2}{(m_3+m_4)^2}T_1 \end{align} | \begin{align} T_\mathrm{max} & =\frac{4m_1m_2}{(m_1+m_2)^2}T_1\\ &= 2m_2 \boldsymbol{v}_\mathrm{cm}^2\\ &\approx 2m_2\boldsymbol{v}_1^2 \end{align} | \begin{align} T_\mathrm{max}=T_1 \end{align} |
Derivation of Quantity 1. Total c.m. energy
The General Formula
They are definitions?
The formula for N-N Scattering
Assuming $m_1=m_2=m_\mathrm{N}$, \begin{align} W &= m_1 + m_2\\ &= 2m_\mathrm{N} \end{align}
Derivation of Quantity 2. c.m. momentum before the interaction
The General Formula
For the center of mass system, \begin{align} \boldsymbol{p}_1^* = \boldsymbol{p}_1 - m_1\boldsymbol{v}_\mathrm{cm}. \end{align} From Quantity 4, the velocity of the c.m. is \begin{align} \boldsymbol{v}_{\rm cm} = \frac{\boldsymbol{p}_1}{m_1+m_2}. \end{align} By substituting this formula into the formula of $\boldsymbol{p}_1^*$, \begin{align} \boldsymbol{p}_1^* &= \boldsymbol{p}_1 - m_1\frac{\boldsymbol{p}_1}{m_1+m_2}\\ &= \frac{m_2}{m_1+m_2}\boldsymbol{p}_1\\ &= \frac{m_1m_2}{m_1+m_2}\boldsymbol{v}_1 \end{align}
The formula for N-N Scattering
Assuming $m_1=m_2=m_\mathrm{N}$, from the general formula,
\begin{align} \boldsymbol{p}_1' = &= \frac{m_2}{m_1+m_2}\boldsymbol{p}_1\\ &= \frac{m_\mathrm{N}}{2m_\mathrm{N}}\boldsymbol{p}_1\\ &= \frac{\boldsymbol{p}_1}{2} \end{align}
Derivation of Quantity 3. c.m. momentum after the interaction
The General Formula
It is almost the same as the derivation of Quantity 2.
The formula for Elastic Scattering
For the elastic scattering, $m_1 = m_3$ and $m_2 = m_4$. Therefore, \begin{align} |\boldsymbol{p}_3^{*}| = |\boldsymbol{p}_1^{*}| \end{align}
The formula for N-N Scattering
For N-N scattering, $m_1 = m_2 = m_3 = m_4 = m_\mathrm{N}$. Therefore,
\begin{align} |\boldsymbol{p}_3'| = |\boldsymbol{p}_1'| = \frac{\boldsymbol{p}_1}{2} \end{align}
Derivation of Quantity 4. Velocity of the c.m.
The General Formula
From the notes below, the velocity of the c.m. $\boldsymbol{v}_{\rm cm}$ of two moving particles is written as
\begin{align} \boldsymbol{v}_{\rm cm} = \frac{\boldsymbol{p}_1+\boldsymbol{p}_2}{m_1+m_2}. \end{align}
If the second particle is not moving, $\boldsymbol{p}_2=0$ and $E_2=m_2$. Therefore, \begin{align} \boldsymbol{v}_{\rm cm} = \frac{\boldsymbol{p}_1}{m_1+m_2}. \end{align}
In the center of mass system, $\boldsymbol{v}_\mathrm{cm}=\boldsymbol{v}_2^*$. As a result,
\begin{align} \boldsymbol{v}_2^* = \boldsymbol{v}_{\rm cm} = \frac{\boldsymbol{p}_1}{m_1+m_2} \end{align}
Derivation of Quantity 5. $\gamma$ of the c.m.
The General Formula
In the non-relativistic limit, \begin{align} \gamma &= \frac{1}{\sqrt{1-|\boldsymbol{\beta}|^2}}\\ &\approx 1? \end{align}
Derivation of Quantity 6. Maximum lab scattering angle
The General Formula
From a equation in the derivation of Quantity 7.,
\begin{align} \tan\theta_3 &= \frac{\sin\theta_3^*}{\delta_{23}^*+\cos\theta_3^*}.\\ \end{align}
By differentiating this equation,
\begin{align} \frac{d(\tan\theta_3)}{d\theta_3^*} &= \frac{\cos\theta_3^*[\delta_{23}^*+\cos\theta_3^*]-\sin\theta_3^*(-\sin\theta_3^*)}{\left(\delta_{23}^*+\cos\theta_3^*\right)^2}\\ &= \frac{\delta_{23}^*\cos^2\theta_3^*+\cos^2\theta_3^*+\cos^2\theta_3^*}{\left(\delta_{23}^*+\cos\theta_3^*\right)^2}\\ &= \frac{\delta_{23}^*\cos\theta_3^*+1}{\left(\delta_{23}^*+\cos\theta_3^*\right)^2}.\\ \end{align}
If $\delta_{23}^*< 1$, $\frac{d(\tan\theta_3)}{d\theta_3^*}>0$. Therefore, the $\tan\theta_3$ becomes maximum and reaches zero at $\theta_3^*=180^\circ$. In this case, $\theta_{3\mathrm{max}} = 180^\circ$.
If $\delta_{23}^*\ge 1$ and $\cos\theta_3^*=-1/\delta_{23}^*$, $\frac{d(\tan\theta_3)}{d\theta_3^*}=0$. Therefore, the $\tan\theta_3$ becomes maximum at \begin{align} \cos\theta_3^*=-1/\delta_{23}^*. \end{align}
By substituting this formula into the formula of $\tan\theta_3$,
\begin{align} \tan\theta_3 &= \frac{\sqrt{1-(1/\delta_{23}^*)^2}}{\delta_{23}^*-1/\delta_{23}^*}\\ &= \frac{\sqrt{\delta_{23}^{*2}-1}}{\delta_{23}^{*2}-1}\\ &= \frac{1}{\sqrt{\delta_{23}^{*2}-1}}.\\ \end{align}
The formula for N-N Scattering
For N-N scattering, $m_1 = m_2 = m_3 = m_4 = m_\mathrm{N}$, and
\begin{align} |\boldsymbol{p}_3'| = |\boldsymbol{p}_1'| = |\boldsymbol{p}_2'|\\ |\boldsymbol{v}_3'| = |\boldsymbol{v}_1'| = |\boldsymbol{v}_2'|\\ \end{align} Therefore, \begin{align} \delta_{23}^* = 1 \end{align}
From a equation in the derivation of Quantity 7.,
\begin{align} \tan\theta_3 &= \frac{\sin\theta_3^*}{\delta_{23}^*+\cos\theta_3^*}.\\ &= \frac{\sin\theta_3^*}{1+\cos\theta_3^*}. \end{align}
Therefore, $\tan\theta_3$ becomes infinite at $\cos\theta_3^*=-1$. In that case, $\theta_\mathrm{3max}=90^\circ$.
Derivation of Quantity 7. c.m. to lab angle ($\theta_{\rm cm} \rightarrow \theta_{\rm lab}$)
The General Formula
\begin{align} |\boldsymbol{v}_3|\cos\theta_{\rm lab} &= |\boldsymbol{v}_3^*|\cos\theta_{\rm cm}+v_{\rm cm}\\ |\boldsymbol{v}_3|\sin\theta_{\rm lab} &= |\boldsymbol{v}_3^*|\sin\theta_{\rm cm} \end{align}
Therefore,
\begin{align} \frac{|\boldsymbol{v}_3|\sin\theta_{\rm lab}}{|\boldsymbol{v}_3|\cos\theta_{\rm lab}} &= \frac{|\boldsymbol{v}_3^*|\sin\theta_{\rm cm}}{|\boldsymbol{v}_3^*|\cos\theta_{\rm cm}+v_{\rm cm}}\\ \tan\theta_{\rm lab} &= \frac{\sin\theta_{\rm cm}}{\cos\theta_{\rm cm}+v_{\rm cm}/|\boldsymbol{v}_3^*|} \end{align} In the center of mass system, $v_\mathrm{cm}=|\boldsymbol{v}_2^*|$. Therefore, \begin{align} v_{\rm cm}/|\boldsymbol{v}_3^*| &= |\boldsymbol{v}_2^*|/|\boldsymbol{v}_3^*|\\ &= \delta_{23}^*. \end{align} By using this formula, $\theta_\mathrm{cm}=\theta_3^*$, and $\theta_\mathrm{lab}=\theta_3$, \begin{align} \tan\theta_3 &= \frac{\sin\theta_3^*}{\delta_{23}^*+\cos\theta_3^*}.\\ \end{align}
By using the relation $\cos\theta=1/\sqrt{1+\tan^2\theta}$, \begin{align} \cos\theta_3 &= \frac{1}{\sqrt{1+\left[\frac{\sin\theta_3^*}{\delta_{23}^*+\cos\theta_3^*}\right]^2}}\\ &= \frac{\delta_{23}^*+\cos\theta_3^*}{\sqrt{\sin^2\theta_3^*+\left(\delta_{23}^*+\cos\theta_3^*\right)^2}} \end{align}
The first formula for Elastic Scattering
For elastic scattering, $m_1 = m_3$ and $|\boldsymbol{p}_3^*| = |\boldsymbol{p}_1^*|$. Therefore,
\begin{align} |\boldsymbol{v}_3^*| = |\boldsymbol{v}_1^*|\\ \delta_{23}^* = \delta_{21}^* \end{align}
From a equation in the derivation of Quantity 7.,
\begin{align} \tan\theta_3 &= \frac{\sin\theta_3^*}{\delta_{23}^*+\cos\theta_3^*}.\\ &= \frac{\sin\theta_3^*}{\delta_{21}^*+\cos\theta_3^*}.\\ \end{align}
The second formula for Elastic Scattering
\begin{align} |\boldsymbol{v}_4|\cos\theta_4 &= -|\boldsymbol{v}_4^*|\cos\theta_4^*+v_{\rm cm}\\ |\boldsymbol{v}_4|\sin\theta_4 &= |\boldsymbol{v}_4^*|\sin\theta_4^* \end{align}
Therefore,
\begin{align} \frac{|\boldsymbol{v}_4|\sin\theta_4}{|\boldsymbol{v}_4|\cos\theta_4} &= \frac{|\boldsymbol{v}_4^*|\sin\theta_4^*}{v_{\rm cm}-|\boldsymbol{v}_4^*|\cos\theta_4^*}\\ \tan\theta_4 &= \frac{\sin\theta_4^*}{v_{\rm cm}/|\boldsymbol{v}_4^*|-\cos\theta_4^*}\\ \end{align}
By using $\theta_4^* = \theta_3^*$ and $v_{\rm cm} = |\boldsymbol{v}_2^*|$, \begin{align} \tan\theta_4 = \frac{\sin\theta_3^*}{|\boldsymbol{v}_2^*|/|\boldsymbol{v}_4^*|-\cos\theta_3^*} \end{align}
For elastic scattering, $m_2=m_4$ and $|\boldsymbol{v}_2^*|=|\boldsymbol{v}_4^*|$. Therefore, \begin{align} \tan\theta_4 = \frac{\sin\theta_3^*}{1-\cos\theta_3^*} \end{align}
In general, $\cot\dfrac{x}{2} = \dfrac{\sin x}{1-\cos x}$. Therefore,
\begin{align} \tan\theta_4 = \cot\frac{\theta_3^*}{2} \end{align}
The formula for N-N Scattering
From an equation in the derivation of Quantity 6., $\delta_{23}^* = 1$. From this equation and an equation in the derivation of Quantity 7.,
\begin{align} \tan\theta_3 &= \frac{\sin\theta_3^*}{\delta_{23}^*+\cos\theta_3^*}.\\ &= \frac{\sin\theta_3^*}{1+\cos\theta_3^*}.\\ \end{align}
Derivation of Quantity 8. lab to c.m. angle transformation ($\theta_\mathrm{cm} \rightarrow \theta_\mathrm{lab}$)
The General Formula
From an equation in the derivation of Quantity 7., \begin{align} \tan\theta_3 &= \frac{\sin\theta_3^*}{\delta_{23}^*+\cos\theta_3^*}.\\ \end{align}
By taking the square of the formula, \begin{align} \tan^2\theta_3 &= \frac{\sin^2\theta_3^*}{\left(\delta_{23}^*+\cos\theta_3^*\right)^2}\\ &= \frac{1-\cos^2\theta_3^*}{\left(\delta_{23}^*+\cos\theta_3^*\right)^2},\\ &\Rightarrow \tan^2\theta_3\left(\delta_{23}^*+\cos\theta_3^*\right)^2=1-\cos^2\theta_3^*\\ &\Rightarrow \left[\tan^2\theta_3+1\right]\cos\theta_3^{*2}+2\delta_{23}^*(\tan^2\theta_3\cos\theta_3^*+\delta_{23}^{*2}\tan^2\theta_3-1=0\\ \end{align}
In general, the solution of the equation \begin{align} ax^2+2bx+c=0 \end{align} is \begin{align} x=-\frac{b}{a}\pm\sqrt{\left(\frac{b}{a}\right)^2-\frac{c}{a}}. \end{align} Therefore, \begin{align} \cos\theta_3^*=-\frac{\delta_{23}^*\tan^2\theta_3}{\tan^2\theta_3+1}\pm\sqrt{\left(\frac{\delta_{23}^*\tan^2\theta_3}{\tan^2\theta_3+1}\right)^2-\frac{\delta_{23}^{*2}\tan^2\theta_3-1}{\tan^2\theta_3+1}}. \end{align}
The another solution
\begin{align} |\boldsymbol{v}_3^*|\cos\theta_{\rm cm} &= |\boldsymbol{v}_3|\cos\theta_{\rm lab}-v_{\rm cm}\\ |\boldsymbol{v}_3^*|\sin\theta_{\rm cm} &= |\boldsymbol{v}_3|\sin\theta_{\rm lab} \end{align}
Therefore,
\begin{align} \frac{|\boldsymbol{v}_3^*|\sin\theta_{\rm cm}}{|\boldsymbol{v}_3^*|\cos\theta_{\rm cm}} &= \frac{|\boldsymbol{v}_3|\sin\theta_{\rm lab}}{|\boldsymbol{v}_3|\cos\theta_{\rm lab}-v_{\rm cm}}\\ \tan\theta_{\rm cm} &= \frac{\sin\theta_{\rm lab}}{\cos\theta_{\rm lab}-v_{\rm cm}/|\boldsymbol{v}_3|}\\ \end{align}
Derivation of Quantity 9. Solid angle transformation (Jacobian)
The first formula of the General Formulae
\begin{align} \frac{d\Omega_3}{d\Omega_3^*} &= \frac{\sin\theta_3d\theta_3d\phi}{\sin\theta_3^*d\theta_3^*d\phi}\\ &= \frac{\sin\theta_3d\theta_3}{\sin\theta_3^*d\theta_3^*}\\ &= \frac{d(\cos\theta_3)}{d(\cos\theta_3^*)}\\ \end{align} By using the Quantity 7. and $(f/g)'=(f'g-fg')/g^2$, \begin{align} \frac{d\Omega_3}{d\Omega_3^*}=\frac{d(\cos\theta_3)}{d(\cos\theta_3^*)} &= \frac{d}{d(\cos\theta_3^*)}\left[\frac{\delta_{23}^*+\cos\theta_3^*}{\sqrt{\sin^2\theta_3^*+\left(\delta_{23}^*+\cos\theta_3^*\right)^2}}\right]\\ &= \left.\left[\frac{d\left(\delta_{23}^*+\cos\theta_3^*\right)}{d(\cos\theta_3^*)}\sqrt{\sin^2\theta_3^*+\left(\delta_{23}^*+\cos\theta_3^*\right)^2}-\left(\delta_{23}^*+\cos\theta_3^*\right)\frac{d\sqrt{\sin^2\theta_3^*+\left(\delta_{23}^*+\cos\theta_3^*\right)^2}}{d(\cos\theta_3^*)}\right]\right/\left[\sin^2\theta_3^*+\left(\delta_{23}^*+\cos\theta_3^*\right)^2\right]\\ &= \left.\left[\frac{d\left(\delta_{23}^*+\cos\theta_3^*\right)}{d(\cos\theta_3^*)}\sqrt{1+\delta_{23}^{*2}+2\delta_{23}^*\cos\theta_3^*}-\left(\delta_{23}^*+\cos\theta_3^*\right)\frac{d\sqrt{1+\delta_{23}^{*2}+2\delta_{23}^*\cos\theta_3^*}}{d(\cos\theta_3^*)}\right]\right/\left[\sin^2\theta_3^*+\left(\delta_{23}^*+\cos\theta_3^*\right)^2\right]\\ &= \left.\left[\sqrt{1+\delta_{23}^{*2}+2\delta_{23}^*\cos\theta_3^*}-\left(\delta_{23}^*+\cos\theta_3^*\right)\frac{1}{2\sqrt{1+\delta_{23}^{*2}+2\delta_{23}^*\cos\theta_3^*}}\frac{d\left(1+\delta_{23}^{*2}+2\delta_{23}^*\cos\theta_3^*\right)}{d(\cos\theta_3^*)}\right]\right/\left[\sin^2\theta_3^*+\left(\delta_{23}^*+\cos\theta_3^*\right)^2\right]\\ &= \left.\left[\sqrt{1+\delta_{23}^{*2}+2\delta_{23}^*\cos\theta_3^*}-\left(\delta_{23}^*+\cos\theta_3^*\right)\frac{1}{2\sqrt{1+\delta_{23}^{*2}+2\delta_{23}^*\cos\theta_3^*}}\cdot 2\delta_{23}^{*}\right]\right/\left[\sin^2\theta_3^*+\left(\delta_{23}^*+\cos\theta_3^*\right)^2\right]\\ &= \left.\left[\left[1+\delta_{23}^{*2}+2\delta_{23}^*\cos\theta_3^*\right]-\delta_{23}^{*}\left(\delta_{23}^*+\cos\theta_3^*\right)\right]\right/\left[\sin^2\theta_3^*+\left(\delta_{23}^*+\cos\theta_3^*\right)^2\right]^{3/2}\\ &= \left.\left[1+\delta_{23}^{*2}+2\delta_{23}^*\cos\theta_3^*-\delta_{23}^{*2}-\delta_{23}^{*}\cos\theta_3^*\right]\right/\left[\sin^2\theta_3^*+\left(\delta_{23}^*+\cos\theta_3^*\right)^2\right]^{3/2}\\ &= \frac{1+\delta_{23}^{*}\cos\theta_3^*}{\left[\sin^2\theta_3^*+\left(\delta_{23}^*+\cos\theta_3^*\right)^2\right]^{3/2}} \end{align}
The second formula of the General Formulae
From Quantity 7., \begin{align} \cos\theta_3 &= \frac{\delta_{23}^*+\cos\theta_3^*}{\sqrt{\sin^2\theta_3^*+\left(\delta_{23}^*+\cos\theta_3^*\right)^2}} \end{align} In general, $\sin\theta=\sqrt{1-\cos^2\theta}$. Therefore, \begin{align} \sin\theta_3 &= \sqrt{1-\left[\frac{\delta_{23}^*+\cos\theta_3^*}{\sqrt{\sin^2\theta_3^*+\left(\delta_{23}^*+\cos\theta_3^*\right)^2}}\right]^2}\\ &= \sqrt{\frac{\sin^2\theta_3^*+\left(\delta_{23}^*+\cos\theta_3^*\right)^2-\left(\delta_{23}^*+\cos\theta_3^*\right)^2}{\sin^2\theta_3^*+\left(\delta_{23}^*+\cos\theta_3^*\right)^2}}\\ &= \sqrt{\frac{1+\delta_{23}^{*2}+2\delta_{23}^*\cos\theta_3^*-\left(\delta_{23}^{*2}+2\delta_{23}^*\cos\theta_3^*+\cos^2\theta_3^*\right)}{\sin^2\theta_3^*+\left(\delta_{23}^*+\cos\theta_3^*\right)^2}}\\ &= \sqrt{\frac{1-\cos^2\theta_3^*}{\sin^2\theta_3^*+\left(\delta_{23}^*+\cos\theta_3^*\right)^2}}\\ &= \sqrt{\frac{\sin^2\theta_3^*}{\sin^2\theta_3^*+\left(\delta_{23}^*+\cos\theta_3^*\right)^2}}\\ &= \frac{\sin\theta_3^*}{\sqrt{\sin^2\theta_3^*+\left(\delta_{23}^*+\cos\theta_3^*\right)^2}}\\ \Rightarrow \frac{\sin\theta_3}{\sin\theta_3^*} &= \frac{1}{\sqrt{\sin^2\theta_3^*+\left(\delta_{23}^*+\cos\theta_3^*\right)^2}} \end{align} By substituting this formula into the first formula of Quantity 9., \begin{align} \frac{d\Omega_3}{d\Omega_3^*} &= \frac{1+\delta_{23}^*\cos\theta_3^*}{\left[\sin^2\theta_3^*+\left(\delta_{23}^*+\cos\theta_3^*\right)^2\right]^{3/2}}\\ &= \frac{\sin^3\theta_3}{\sin^3\theta_3^*}(1+\delta_{23}^*\cos\theta_3^*)\\ \end{align}
The formula for N-N Scattering
From an equation in the derivation of Quantity 6., $\delta_{23}^* = 1$. Therefore, the first formula of the General Formulae of Quantity 9. can be written as
\begin{align} \frac{d\Omega_3}{d\Omega_3^*} &= \frac{1+\delta_{23}^{*}\cos\theta_3^*}{\left[\sin^2\theta_3^*+\left(\delta_{23}^*+\cos\theta_3^*\right)^2\right]^{3/2}}\\ &= \frac{1+\delta_{23}^{*}\cos\theta_3^*}{\left[1+\delta_{23}^{*2}+2\delta_{23}^*\cos\theta_3^*\right]^{3/2}}\\ &= \frac{1+\cos\theta_3^*}{\left[2+2\cos\theta_3^*\right]^{3/2}}\\ &= \frac{1+\cos\theta_3^*}{\left[2\left(1+\cos\theta_3^*\right)\right]^{3/2}}\\ &= \frac{1}{2^{3/2}\sqrt{1+\cos\theta_3^*}} \end{align}
Derivation of Quantity 11. Lab quantity relations
The first formula of the General Formulae
From the law of conservation of momentum, \begin{align} &&|\boldsymbol{p}_1| = |\boldsymbol{p}_3|\cos\theta_3 + |\boldsymbol{p}_4|\cos\theta_4,\\ &&|\boldsymbol{p}_3|\sin\theta_3 = |\boldsymbol{p}_4|\sin\theta_4.\\ \end{align} By moving $|\boldsymbol{p}_3|\cos\theta_3$ to left and making squares for the both sides of each formula, \begin{align} \boldsymbol{p}_1^2 + \boldsymbol{p}_3^2\cos^2\theta_3 -2|\boldsymbol{p}_1||\boldsymbol{p}_3|\cos\theta_3 &= \boldsymbol{p}_4^2\cos^2\theta_4,\\ \boldsymbol{p}_3^2\sin^2\theta_3 &= \boldsymbol{p}_4^2\sin^2\theta_4.\\ \end{align} By summing these formulae, \begin{align} \boldsymbol{p}_1^2 + (\boldsymbol{p}_3^2\cos^2\theta_3+\boldsymbol{p}_3^2\sin^2\theta_3) -2|\boldsymbol{p}_1||\boldsymbol{p}_3|\cos\theta_3 &= \boldsymbol{p}_4^2\cos^2\theta_4+\boldsymbol{p}_4^2\sin^2\theta_4,\\ \boldsymbol{p}_1^2 + \boldsymbol{p}_3^2 -2|\boldsymbol{p}_1||\boldsymbol{p}_3|\cos\theta_3 &= \boldsymbol{p}_4^2.\\ \end{align}
(N.B. This formula can be obtained directly by taking square of the both sides of the relation $\boldsymbol{p}_1=\boldsymbol{p}_3+\boldsymbol{p}_4 \Leftrightarrow \boldsymbol{p}_1-\boldsymbol{p}_3=\boldsymbol{p}_4$)
Then, \begin{align} 2|\boldsymbol{p}_1||\boldsymbol{p}_3|\cos\theta_3 &= \boldsymbol{p}_1^2 + \boldsymbol{p}_3^2 - \boldsymbol{p}_4^2. \end{align}
The second formula of the General Formulae
From the law of conservation of momentum in the direction of $\boldsymbol{p}_3$, \begin{align} |\boldsymbol{p}_1|\cos\theta_3 &= |\boldsymbol{p}_3|+|\boldsymbol{p}_4|\cos(\theta_3+\theta_4)\\ \Rightarrow 2|\boldsymbol{p}_1||\boldsymbol{p}_3|\cos\theta_3 &= 2\boldsymbol{p}_3^2+2|\boldsymbol{p}_3||\boldsymbol{p}_4|\cos(\theta_3+\theta_4)\\ \Rightarrow 2|\boldsymbol{p}_3||\boldsymbol{p}_4|\cos(\theta_3+\theta_4) &= 2|\boldsymbol{p}_1||\boldsymbol{p}_3|\cos\theta_3-2\boldsymbol{p}_3^2\\ \end{align} By substituting the first formula of the Quantity 11. Lab quantity relations into this formula, \begin{align} 2|\boldsymbol{p}_3||\boldsymbol{p}_4|\cos(\theta_3+\theta_4) &= \boldsymbol{p}_1^2 + \boldsymbol{p}_3^2 - \boldsymbol{p}_4^2 -2\boldsymbol{p}_3^2\\ &= \boldsymbol{p}_1^2 - \boldsymbol{p}_3^2 - \boldsymbol{p}_4^2 \end{align}
The formula for N-N Scattering
From the law of conservation of energy,
\begin{align} \frac{\boldsymbol{p}_1^2}{2m_1} = \frac{\boldsymbol{p}_3^2}{2m_3} + \frac{\boldsymbol{p}_4^2}{2m_4} \end{align}
For N-N scattering, $m_1 = m_2 = m_3 = m_4 = m_\mathrm{N}$. Therefore,
\begin{align} \boldsymbol{p}_1^2 = \boldsymbol{p}_3^2 + \boldsymbol{p}_4^2. \end{align}
From this formula and the General formula, \begin{align} 2|\boldsymbol{p}_3||\boldsymbol{p}_4|\cos(\theta_3+\theta_4) &= \boldsymbol{p}_1^2 - \boldsymbol{p}_3^2 - \boldsymbol{p}_4^2\\ &= 0 \end{align}
Therefore, \begin{align} \cos(\theta_3+\theta_4) &= 0\\ \theta_3+\theta_4 &= 90^\circ. \end{align}
Derivation of Quantity 12. Maximum K.E. transfer to a stationary particle
The General Formula
\begin{align} |\boldsymbol{v}_4|\cos\theta_4 &= -|\boldsymbol{v}_4^*|\cos\theta_4^*+v_{\rm cm}\\ |\boldsymbol{v}_4|\sin\theta_4 &= |\boldsymbol{v}_4^*|\sin\theta_4^* \end{align}
By taking the squares for the both sides,
\begin{align} |\boldsymbol{v}_4|^2\cos^2\theta_4 &= |\boldsymbol{v}_4^*|^2\cos^2\theta_4^*+v_{\rm cm}^2-2v_{\rm cm}|\boldsymbol{v}_4^*|\cos\theta_4^*\\ |\boldsymbol{v}_4|^2\sin^2\theta_4 &= |\boldsymbol{v}_4^*|^2\sin^2\theta_4^*. \end{align}
By adding each side,
\begin{align} |\boldsymbol{v}_4|^2(\sin^2\theta_4+\cos^2\theta_4) &= |\boldsymbol{v}_4^*|^2(\sin^2\theta_4^*+\cos^2\theta_4^*)+v_{\rm cm}^2-2v_{\rm cm}|\boldsymbol{v}_4^*|\cos\theta_4^*\\ \Rightarrow |\boldsymbol{v}_4|^2 &= |\boldsymbol{v}_4^*|^2+v_{\rm cm}^2-2v_{\rm cm}|\boldsymbol{v}_4^*|\cos\theta_4^* \end{align}
Therefore, $|\boldsymbol{v}_4|$ becomes maximum at $\theta_4^* = \theta_\mathrm{cm}=180^\circ$. In this case, $\theta_4 = 0^\circ$ and $\boldsymbol{v}_4$ has the same direction as $\boldsymbol{v}_1$. From the law of conservation of energy and momentum,
\begin{align} T_1 &= T_3 + T_4\\ \boldsymbol{p}_1 &= \boldsymbol{p}_3 + \boldsymbol{p}_4. \end{align}
In general, $T = \frac{\boldsymbol{p}^2}{2m}$. Therefore, the first equation is written as \begin{align} \frac{\boldsymbol{p}_1^2}{2m_1} &= \frac{\boldsymbol{p}_3^2}{2m_3} + \frac{\boldsymbol{p}_4^2}{2m_4}\\ \Rightarrow \frac{\boldsymbol{p}_1^2}{m_1} &= \frac{\boldsymbol{p}_3^2}{m_3} + \frac{\boldsymbol{p}_4^2}{m_4} \end{align}
By substituting $\boldsymbol{p}_3 = \boldsymbol{p}_1 - \boldsymbol{p}_4$ into this formula,
\begin{align} \frac{\boldsymbol{p}_1^2}{m_1} &= \frac{(\boldsymbol{p}_1 - \boldsymbol{p}_4)^2}{m_3} + \frac{\boldsymbol{p}_4^2}{m_4}\\ &= \frac{\boldsymbol{p}_1^2 - 2|\boldsymbol{p}_1||\boldsymbol{p}_4|\cos\theta_4 + \boldsymbol{p}_4^2}{m_3} + \frac{\boldsymbol{p}_4^2}{m_4}\\ &= \frac{\boldsymbol{p}_1^2 - 2|\boldsymbol{p}_1||\boldsymbol{p}_4| + \boldsymbol{p}_4^2}{m_3} + \frac{\boldsymbol{p}_4^2}{m_4}. \end{align}
Therefore, by using $\boldsymbol{p}^2=|\boldsymbol{p}|^2$,
\begin{align} \left(\frac{1}{m_3}+\frac{1}{m_4}\right)|\boldsymbol{p}_4|^2-\frac{2|\boldsymbol{p}_1|}{m_3}|\boldsymbol{p}_4|+\left(\frac{1}{m_3}-\frac{1}{m_1}\right)|\boldsymbol{p}_1|^2=0\\ \end{align}
In general, the solution of the equation $ax^2-2bx+c=0$ is $x=\frac{b\pm\sqrt{b^2-ac}}{a}$. Therefore, \begin{align} |\boldsymbol{p}_4| &=\frac{\frac{|\boldsymbol{p}_1|}{m_3}\pm\sqrt{\frac{|\boldsymbol{p}_1|^2}{m_3^2}-\left(\frac{1}{m_3}+\frac{1}{m_4}\right)\left(\frac{1}{m_3}-\frac{1}{m_1}\right)|\boldsymbol{p}_1|^2}}{\frac{1}{m_3}+\frac{1}{m_4}}\\ &=\frac{\frac{1}{m_3}\pm\sqrt{\frac{1}{m_3^2}-\left(\frac{1}{m_3}+\frac{1}{m_4}\right)\left(\frac{1}{m_3}-\frac{1}{m_1}\right)}}{\frac{1}{m_3}+\frac{1}{m_4}}|\boldsymbol{p}_1|\\ &=\frac{\frac{1}{m_3}\pm\sqrt{\frac{1}{m_3^2}-\left(\frac{1}{m_3^2}-\frac{1}{m_1m_3}-\frac{1}{m_1m_4}+\frac{1}{m_3m_4}\right)}}{\frac{1}{m_3}+\frac{1}{m_4}}|\boldsymbol{p}_1|\\ &=\frac{\frac{1}{m_3}\pm\sqrt{\frac{1}{m_1m_3}+\frac{1}{m_1m_4}-\frac{1}{m_3m_4}}}{\frac{1}{m_3}+\frac{1}{m_4}}|\boldsymbol{p}_1|\\ &=\frac{\frac{1}{m_3}\pm\sqrt{\frac{1}{m_1m_3}+\frac{1}{m_1m_4}-\frac{1}{m_3m_4}}}{\frac{m_3+m_4}{m_3m_4}}|\boldsymbol{p}_1|\\ &=\frac{m_4\pm\sqrt{m_3m_4}\sqrt{\frac{m_3}{m_1}+\frac{m_4}{m_1}-1}}{m_3+m_4}|\boldsymbol{p}_1|\\ &=\frac{m_4\pm\sqrt{\frac{m_3m_4}{m_1}}\sqrt{m_3+m_4-m_1}}{m_3+m_4}|\boldsymbol{p}_1|\\ \end{align}
The direction of $\boldsymbol{p}_4$ is the same as $\boldsymbol{p}_1$, then \begin{align} \boldsymbol{p}_4 &=\frac{m_4\pm\sqrt{\frac{m_3m_4}{m_1}}\sqrt{m_3+m_4-m_1}}{m_3+m_4}\boldsymbol{p}_1. \end{align}
From $\boldsymbol{p}_3=\boldsymbol{p}_1-\boldsymbol{p}_4$, \begin{align} \boldsymbol{p}_3 &= \boldsymbol{p}_1-\boldsymbol{p}_4\\ &= \boldsymbol{p}_1-\frac{m_4\pm\sqrt{\frac{m_3m_4}{m_1}(m_3+m_4-m_1)}}{m_3+m_4}\boldsymbol{p}_1\\ &= \frac{m_3+m_4-m_4\mp\sqrt{\frac{m_3m_4}{m_1}(m_3+m_4-m_1)}}{m_3+m_4}\boldsymbol{p}_1\\ &= \frac{m_3\mp\sqrt{\frac{m_3m_4}{m_1}(m_3+m_4-m_1)}}{m_3+m_4}\boldsymbol{p}_1\\ \end{align}
By using $T_4=\frac{|\boldsymbol{p}_4|^2}{2m_4}$ and $T_1=\frac{|\boldsymbol{p}_1|^2}{2m_1}$,
\begin{align} T_4 &=\frac{|\boldsymbol{p}_4|^2}{2m_4}\\ &=\frac{1}{2m_4}\frac{\left[m_4\pm\sqrt{\frac{m_3m_4}{m_1}}\sqrt{m_3+m_4-m_1}\right]^2}{(m_3+m_4)^2}|\boldsymbol{p}_1|^2\\ &=\frac{m_1}{m_4}\frac{\left[m_4\pm\sqrt{\frac{m_3m_4}{m_1}}\sqrt{m_3+m_4-m_1}\right]^2}{(m_3+m_4)^2}\frac{|\boldsymbol{p}_1|^2}{2m_1}\\ &=\frac{m_1}{m_4}\frac{\left[m_4\pm\sqrt{\frac{m_3m_4}{m_1}}\sqrt{m_3+m_4-m_1}\right]^2}{(m_3+m_4)^2}T_1\\ &=\frac{\left[\sqrt{\frac{m_1}{m_4}}m_4\pm\sqrt{\frac{m_1}{m_4}}\sqrt{\frac{m_3m_4}{m_1}}\sqrt{m_3+m_4-m_1}\right]^2}{(m_3+m_4)^2}T_1\\ &=\frac{\left[\sqrt{m_1m_4}\pm\sqrt{m_3(m_3+m_4-m_1)}\right]^2}{(m_3+m_4)^2}T_1. \end{align}
As a result,
\begin{align} T_\mathrm{max} = T_4 &=\frac{\left[\sqrt{m_1m_4}\pm\sqrt{m_3(m_3+m_4-m_1)}\right]^2}{(m_3+m_4)^2}T_1. \end{align}
By the way, from $T_3=T_1-T_4$, $T_3$ is
\begin{align} T_3 &= T_1-T_4\\ &= T_1-\frac{\left[\sqrt{m_1m_4}\pm\sqrt{m_3(m_3+m_4-m_1)}\right]^2}{(m_3+m_4)^2}T_1\\ &= T_1-\frac{\sqrt{m_1m_4}^2+\sqrt{m_3(m_3+m_4-m_1)}^2\pm2\sqrt{m_1m_4}\sqrt{m_3(m_3+m_4-m_1)}}{(m_3+m_4)^2}T_1\\ &= T_1-\frac{m_1m_4+m_3(m_3+m_4-m_1)\pm2\sqrt{m_1m_4}\sqrt{m_3(m_3+m_4-m_1)}}{(m_3+m_4)^2}T_1\\ &= T_1-\frac{m_1m_4-m_1m_3+m_3^2+m_3m_4\pm2\sqrt{m_1m_4}\sqrt{m_3(m_3+m_4-m_1)}}{(m_3+m_4)^2}T_1\\ &= \frac{(m_3+m_4)^2 -m_1m_4+m_1m_3-m_3^2-m_3m_4\mp2\sqrt{m_1m_4}\sqrt{m_3(m_3+m_4-m_1)}}{(m_3+m_4)^2}T_1\\ &= \frac{m_3^2+2m_3m_4+m_4^2-m_1m_4+m_1m_3-m_3^2-m_3m_4\mp2\sqrt{m_1m_4}\sqrt{m_3(m_3+m_4-m_1)}}{(m_3+m_4)^2}T_1\\ &= \frac{m_1m_3+m_3m_4+m_4^2-m_1m_4\mp2\sqrt{m_1m_4}\sqrt{m_3(m_3+m_4-m_1)}}{(m_3+m_4)^2}T_1\\ &= \frac{m_1m_3+m_4(m_3+m_4-m_1)\mp2\sqrt{m_1m_4}\sqrt{m_3(m_3+m_4-m_1)}}{(m_3+m_4)^2}T_1\\ &= \frac{\sqrt{m_1m_3}^2+\sqrt{m_4(m_3+m_4-m_1)}^2\mp2\sqrt{m_1m_4}\sqrt{m_3(m_3+m_4-m_1)}}{(m_3+m_4)^2}T_1\\ &= \frac{\left[\sqrt{m_1m_3}\mp\sqrt{m_4(m_3+m_4-m_1)}\right]^2}{(m_3+m_4)^2}T_1 \end{align}
The first formula for elastic scattering
For elastic scattering, $m_3 = m_1$ and $m_4 = m_2$. Therefore, \begin{align} \boldsymbol{p}_4&=\frac{2m_2}{m_1+m_2}\boldsymbol{p}_1\\ \boldsymbol{p}_3&=\frac{m_1-m_2}{m_1+m_2}\boldsymbol{p}_1\\ T_4&=\frac{4m_1m_2}{(m_1+m_2)^2}T_1\\ &=\frac{2m_2\boldsymbol{p}_1^2}{(m_1+m_2)^2}\\ &=2m_2\boldsymbol{v}_\mathrm{cm}\\ T_3&=\frac{(m_1- m_2)^2}{(m_1+m_2)^2}T_1 \end{align} As a result,
\begin{align} T_\mathrm{max}=T_4=\frac{4m_1m_2}{(m_1+m_2)^2}T_1 \end{align}
Another derivation of the first formula for elastic scattering
From the above discussion, $|\boldsymbol{v}_4|$ becomes maximum at $\theta_4^* = \theta_\mathrm{cm}=180^\circ$. In this case, $\theta_4 = 0^\circ$ and $\boldsymbol{v}_4$ has the same direction as $\boldsymbol{v}_1$. For $\theta_4 = 0^\circ$, from the law of conservation of energy and momentum,
\begin{align} \frac{1}{2}m_1\boldsymbol{v}_1^2 = \frac{1}{2}m_1\boldsymbol{v}_3^2 + \frac{1}{2}m_2\boldsymbol{v}_4^2\\ m_1\boldsymbol{v}_1 = m_1\boldsymbol{v}_3 + m_2\boldsymbol{v}_4\\ \end{align}
From the second equation, \begin{align} \boldsymbol{v}_3 = \frac{m_1\boldsymbol{v}_1 - m_2\boldsymbol{v}_4}{m_1}. \end{align}
By substituting this formula into the formula of the law of conservation of energy,
\begin{align} \frac{1}{2}m_1\boldsymbol{v}_1^2 &= \frac{1}{2}m_1\frac{(m_1\boldsymbol{v}_1 - m_2\boldsymbol{v}_4)^2}{m_1^2} + \frac{1}{2}m_2\boldsymbol{v}_4^2\\ &= \frac{1}{2}m_1\frac{m_1^2\boldsymbol{v}_1^2 + m_2^2\boldsymbol{v}_4^2 - 2m_1m_2|\boldsymbol{v}_1||\boldsymbol{v}_4|}{m_1^2} + \frac{1}{2}m_2\boldsymbol{v}_4^2\\ \Rightarrow 0 &= \frac{1}{2}m_1\frac{m_2^2\boldsymbol{v}_4^2 - 2m_1m_2|\boldsymbol{v}_1||\boldsymbol{v}_4|}{m_1^2} + \frac{1}{2}m_2\boldsymbol{v}_4^2 \\ \Rightarrow 0 &= \frac{m_2|\boldsymbol{v}_4| - 2m_1|\boldsymbol{v}_1|}{m_1} + |\boldsymbol{v}_4| \\ \Rightarrow 2|\boldsymbol{v}_1| &= \left(\frac{m_2}{m_1}+1\right)|\boldsymbol{v}_4|\\ \Rightarrow |\boldsymbol{v}_4| &= 2\frac{1}{\frac{m_2}{m_1}+1}|\boldsymbol{v}_1|\\ &= \frac{2m_1}{m_1+m_2}|\boldsymbol{v}_1|\\ \Rightarrow \boldsymbol{v}_4^2 &= \frac{4m_1^2}{(m_1+m_2)^2}\boldsymbol{v}_1^2\\ \Rightarrow \frac{1}{2}m_4\boldsymbol{v}_4^2 &= \frac{4m_4m_1}{(m_1+m_2)^2}\frac{1}{2}m_1\boldsymbol{v}_1^2\\ \Rightarrow T_\mathrm{max} &= T_4 = \frac{4m_4m_1}{(m_1+m_2)^2}T_1\\ \end{align}
The second formula for elastic scattering
From the first formula, \begin{align} T_\mathrm{max} &=\frac{4m_1m_2}{(m_1+m_2)^2}T_1\\ &=\frac{2m_2\boldsymbol{p}_1^2}{(m_1+m_2)^2}\\ &=\frac{2m_2m_1^2\boldsymbol{v}_1^2}{(m_1+m_2)^2}\\ &=\frac{2m_2\boldsymbol{v}_1^2}{(1+m_2/m_1)^2}\\ \end{align} If $m_2/m_1 \ll 1$, \begin{align} T_\mathrm{max} &=\frac{2m_2\boldsymbol{v}_1^2}{(1+m_2/m_1)^2}\\ &\approx 2m_2\boldsymbol{v}_1^2.\\ \end{align}
Another derivation of the second formula for elastic scattering
If $m_2/m_1 \ll 1$, $|\boldsymbol{v}_\mathrm{cm}| \approx |\boldsymbol{v}_1|$. Therefore, from the formula above, \begin{align} T_\mathrm{max} &= 2m_2 \boldsymbol{v}_\mathrm{cm}^2\\ &\approx 2m_2\boldsymbol{v}_1^2.\\ \end{align}
The formula for N-N scattering
For N-N scattering, $m_1 = m_2 = m_\mathrm{N}$. Therefore, from the formula above, \begin{align} T_\mathrm{max} &=\frac{4m_1m_2}{(m_1+m_2)^2}T_1\\ &=\frac{4m_\mathrm{N}m_\mathrm{N}}{(m_\mathrm{N}+m_\mathrm{N})^2}T_1\\ &=\frac{4m_\mathrm{N}^2}{(2m_\mathrm{N})^2}T_1\\ &=T_1 \end{align}
General memo
Galilean transformation
\begin{align} \boldsymbol{p}^* &=m(\boldsymbol{v}-\boldsymbol{v}_0)\\ &=\boldsymbol{p}-m\boldsymbol{v}_0 \end{align}
So, this equation can be written in another way.
\begin{align} \begin{pmatrix} m\\ \boldsymbol{p}^* \end{pmatrix} = \begin{pmatrix} 1 & 0 \\ -\boldsymbol{v}_0 & 1\\ \end{pmatrix} \begin{pmatrix} m\\ \boldsymbol{p} \end{pmatrix} \end{align}
Velocity of the center of mass $\boldsymbol{v}_\mathrm{cm}$
In the center of mass frame, the sum of the momenta of the particles ($\boldsymbol{p}_1^* + \boldsymbol{p}_2^*$) should be $0$. Therefore, $\boldsymbol{v}_{\rm cm}$ can be obtained by solving the following equation for $\boldsymbol{v}_0$. \begin{align} 0 &= \boldsymbol{p}_1^* + \boldsymbol{p}_2^*\\ &= \boldsymbol{p}_1-m_1\boldsymbol{v}_0 + \boldsymbol{p}_2-m_2\boldsymbol{v}_0\\ \end{align} By solving the equation for $\boldsymbol{v}_0$, \begin{align} \boldsymbol{v}_0 = \frac{\boldsymbol{p}_1 + \boldsymbol{p}_2}{m_1+m_2}. \end{align} Therefore, the $\boldsymbol{v}_\mathrm{cm}$ is \begin{align} \boldsymbol{v}_\mathrm{cm} &= \frac{\boldsymbol{p}_1 + \boldsymbol{p}_2}{m_1+m_2}\\ &= \frac{m_1\boldsymbol{v}_1 + m_2\boldsymbol{v}_2}{m_1+m_2} \end{align}