差分

このページの2つのバージョン間の差分を表示します。

--- research:memos:kinematics:relativistic_kinematics [2022/01/04 17:47] – [TRIUMF Kinematics Handbook: Sec. V Relativistic Kinematics] kobayash
+++ research:memos:kinematics:relativistic_kinematics [2022/01/09 12:16] (現在) – [TRIUMF Kinematics Handbook: Sec. V Relativistic Kinematics] kobayash
@@ 行 59: / 行 59: @@
 \end{align} N.B. $\theta_3^* = \theta_4^*$ |\begin{align}
 \tan\theta_3 &= \frac{\sin\theta_3^*}{\gamma_2^*\left(\delta_{21}^*+\cos\theta_3^*\right)}\\
-\tan\theta_4 &= \frac{1}{\gamma_2^*}\cot\frac{\theta_3^*}{2}\\
+\tan\theta_4 &= \frac{1}{\gamma_2^*}\cot\frac{\theta_3^*}{2}
-&= \frac{1}{\gamma_2^*}\cot\frac{\theta_4^*}{2}
+\end{align} N.B. $\theta_3^* = \theta_4^*$|\begin{align}
-\end{align}|\begin{align}
 \tan\theta_3 = \frac{\sin\theta_3^*}{\gamma_2^*\left(1+\cos\theta_3^*\right)}\\
-\end{align}|
+\end{align} N.B. $\theta_3^* = \theta_4^*$|
 | 8. lab to c.m. angle transformation ($\theta_\mathrm{lab} \rightarrow \theta_\mathrm{cm}$) |\begin{align}
 \cos\theta_3^*=-\frac{\delta_{23}^*(\gamma_2^*\tan\theta_3)^2}{(\gamma_2^*\tan\theta_3)^2+1}\pm\sqrt{\left(\frac{\delta_{23}^*(\gamma_2^*\tan\theta_3)^2}{(\gamma_2^*\tan\theta_3)^2+1}\right)^2-\frac{\delta_{23}^{*2}(\gamma_2^*\tan\theta_3)^2-1}{(\gamma_2^*\tan\theta_3)^2+1}}
@@ 行 97: / 行 96: @@
 \end{align}|
-=== Derivation of Quantity 1. Total c.m. energy ===
+==== Derivation of Quantity 1. Total c.m. energy ====
 ** The General Formula **
@@ 行 112: / 行 111: @@
 \end{align}
-=== Derivation of Quantity 2. c.m. momentum before the interaction ===
+==== Derivation of Quantity 2. c.m. momentum before the interaction ====
 ** The General Formula **
@@ 行 168: / 行 167: @@
 \end{align}
-=== Derivation of Quantity 3. c.m. momentum after the interaction ===
+==== Derivation of Quantity 3. c.m. momentum after the interaction ====
 ** The General Formula **
@@ 行 191: / 行 190: @@
 \end{align}
-=== Derivation of Quantity 4. Velocity of the c.m. ===
+==== Derivation of Quantity 4. Velocity of the c.m. ====
 ** The General Formula **
@@ 行 211: / 行 210: @@
 \end{align}
-=== Derivation of Quantity 5. $\gamma$ of the c.m. ===
+==== Derivation of Quantity 5. $\gamma$ of the c.m. ====
 ** The General Formula **
@@ 行 236: / 行 235: @@
-=== Derivation of Quantity 6. Maximum lab scattering angle ===
+==== Derivation of Quantity 6. Maximum lab scattering angle ====
 ** The General Formula **
@@ 行 293: / 行 292: @@
 Therefore, $\tan\theta_3$ becomes infinite at $\cos\theta_3^*=-1$. In that case, $\mathrm{3max}=90^\circ$.
-=== Derivation of Quantity 7. c.m. to lab angle ($\theta_{\rm cm} \rightarrow \theta_{\rm lab}$) ===
+==== Derivation of Quantity 7. c.m. to lab angle ($\theta_{\rm cm} \rightarrow \theta_{\rm lab}$) ====
 ** The General Formula **
@@ 行 395: / 行 394: @@
 By using $\theta_4^* = \theta_3^*$, $\beta_{\rm cm} = |\boldsymbol{\beta}_2^*|$ and $\gamma_{\rm cm} = \gamma_2^*$,
 \begin{align}
-\tan\theta_4 = \frac{\sin\theta_3^*}{\gamma_2^*\left(|\boldsymbol{\beta}_2^*|/|\boldsymbol{\beta}_4^*|-\cos\theta_3^*\right)}
+\tan\theta_4
+&= \frac{\sin\theta_3^*}{\gamma_2^*\left(|\boldsymbol{\beta}_2^*|/|\boldsymbol{\beta}_4^*|-\cos\theta_3^*\right)}\\
+&= \frac{\sin\theta_3^*}{\gamma_2^*\left(\delta_{24}^*-\cos\theta_3^*\right)}
 \end{align}
-For elastic scattering, $m_2=m_4$, $|\boldsymbol{p}_2^*|=|\boldsymbol{p}_4^*|$, and $|\boldsymbol{\beta}_2^*|=|\boldsymbol{\beta}_4^*|$. Therefore,
+For elastic scattering, $m_2=m_4$, $|\boldsymbol{p}_2^*|=|\boldsymbol{p}_4^*|$, $|\boldsymbol{\beta}_2^*|=|\boldsymbol{\beta}_4^*|$, and $\delta_{24}^*=1$. Therefore,
 \begin{align}
 \tan\theta_4 = \frac{\sin\theta_3^*}{\gamma_2^*(1-\cos\theta_3^*)}
@@ 行 420: / 行 421: @@
 \end{align}
-=== Derivation of Quantity 8. lab to c.m. angle transformation ($\theta_\mathrm{cm} \rightarrow \theta_\mathrm{lab}$) ===
+==== Derivation of Quantity 8. lab to c.m. angle transformation ($\theta_\mathrm{cm} \rightarrow \theta_\mathrm{lab}$) ====
 ** The General Formula **
@@ 行 479: / 行 480: @@
 \end{align}
-=== Derivation of Quantity 9. Solid angle transformation (Jacobian) ===
+==== Derivation of Quantity 9. Solid angle transformation (Jacobian) ====
 ** The first formula of the General Formulae **
@@ 行 539: / 行 540: @@
 \end{align}
-===  Derivation of Quantity 10. Relations between the $\gamma$ factors ===
+====  Derivation of Quantity 10. Relations between the $\gamma$ factors ====
 ** The first formula of the General Formulae **
@@ 行 633: / 行 634: @@
-=== Derivation of Quantity 11. Lab quantity relations ===
+==== Derivation of Quantity 11. Lab quantity relations ====
 ** The first formula of the General Formulae **
@@ 行 724: / 行 725: @@
-=== Derivation of Quantity 12. Maximum K.E. transfer to a stationary particle ===
+==== Derivation of Quantity 12. Maximum K.E. transfer to a stationary particle ====