Latest revision as of 19:07, 1 January 2019

$\underline{\textbf{Navigation}}$

$\vartriangleleft$ $\triangle$ $\vartriangleright$

Limits based on Mandelstam Variables

Since the Mandelstam variables are the scalar product of 4-momenta, which are invariants, they are invariants as well. The sum of these invariant variables must also be invariant as well. Find the sum of the 3 Mandelstam variables when the two particles have equal mass in the center of mass frame gives:

$s+t+u=(4(m^2+ p \ ^{*2}))+(-2 p \ ^{*2}(1-cos\ \theta))+(-2 p \ ^{*2}(1+cos\ \theta))$

$s+t+u \equiv 4m^2$

Since

$s \equiv 4(m^2+\vec p \ ^{*2})$

This implies

$s \ge 4m^2$

In turn, this implies

$t \le 0 \qquad u \le 0$

At the condition both t and u are equal to zero, we find

$t = 0 \qquad u = 0$

$-2 p \ ^{*2}(1-cos\ \theta) = 0 \qquad -2 p \ ^{*2}(1+cos\ \theta) = 0$

$(-2 p \ ^{*2}+2 p \ ^{*2}cos\ \theta) = 0 \qquad (-2 p \ ^{*2}-2 p \ ^{*2}cos\ \theta) = 0$

$2 p \ ^{*2}cos\ \theta = 2 p \ ^{*2} \qquad -2 p \ ^{*2}cos\ \theta = 2 p \ ^{*2}$

$\cos\ \theta = 1 \qquad \cos\ \theta = -1$

$\Rightarrow \theta_{t=0} = \arccos \ 1=0^{\circ} \qquad \theta_{u=0} = \arccos \ -1=180^{\circ}$

Holding u constant at zero we can find the minimum of t

$s+t_{max} \equiv 4m^2$

$\Rightarrow t_{max}=4m^2-s$

$t_{max}=4m^2-4m^2- 4p \ ^{*2}$

The maximum transfer of momentum would be

$t_{max}=-4p \ ^{*2}$

$-2 p \ ^{*2}(1-cos\ \theta_{t=max})=-4p \ ^{*2}$

$(1-cos\ \theta_{t=max})=2$

$-cos\ \theta_{t=max}=1$

$\theta_{t=max} \equiv \arccos -1$

The domain of the arccos function is from −1 to +1 inclusive and the range is from 0 to π radians inclusive (or from 0° to 180°). We find as expected for u=0 at $\theta=180^{\circ}$

$\theta_{t=max}=180^{\circ}$

However, from the definition of s being invariant between frames of reference

$s \equiv \overbrace{\left({\mathbf P_1^*}+ {\mathbf P_2^{*}}\right)^2=\left({\mathbf P_1^{'*}}+ {\mathbf P_2^{'*}}\right)^2}^{CM\ FRAME}=\overbrace{\left({\mathbf P_1}+ {\mathbf P_2}\right)^2 = \left({\mathbf P_1^{'}}+ {\mathbf P_2^{'}}\right)^2}^{LAB\ FRAME}$

In the center of mass frame of reference,

$E_1^*=E_2^*=E^* \quad and \quad \vec p \ _1^*=-\vec p \ _2^*= \vec p \ ^*$

$s \equiv 2m^2+2(E_1^{*2}+\vec p \ ^{*2} )$

Using the relativistic energy equation

$E^2 \equiv \vec p \ ^2+m^2$

$s \equiv 2m^2+2((m^2+\vec p \ ^{*2})+\vec p \ ^{*2})$

$s=4m^2+4 \vec p \ ^{*2})$

$\frac{s-4m^2}{4}= \vec p \ ^{*2}$

$t=-2 p \ ^{*2}(1-cos\ \theta)=\frac{-2(s-4m^2)}{4}(1-cos\ \theta)$

$\frac{-2t}{s-4m^2}=(1-cos\ \theta)$

$cos\ \theta=1-\frac{-2t}{s-4m^2}$

$\underline{\textbf{Navigation}}$

$\vartriangleleft$ $\triangle$ $\vartriangleright$

@@ Line 1: / Line 1: @@
-<center><math>\textbf{\underline{Navigation}}</math>
+<center><math>\underline{\textbf{Navigation}}</math>
 [[U-Channel|<math>\vartriangleleft </math>]]
 [[VanWasshenova_Thesis#Moller_Scattering|<math>\triangle </math>]]
-[[Limits_based_on_Mandelstam_Variables|<math>\vartriangleright </math>]]
+[[Limit_of_Energy_in_Lab_Frame|<math>\vartriangleright </math>]]
 </center>
@@ Line 61: / Line 61: @@
 <center><math>\Rightarrow  \theta_{t=0} = \arccos \ 1=0^{\circ}  \qquad \theta_{u=0} = \arccos \ -1=180^{\circ}</math></center>
-Holding u constant at zero we can find the maximum of t
+Holding u constant at zero we can find the minimum of t
-<center><math>s+t \equiv 4m^2</math></center>
+<center><math>s+t_{max} \equiv 4m^2</math></center>
-<center><math>\Rightarrow t=4m^2-s</math></center>
+<center><math>\Rightarrow t_{max}=4m^2-s</math></center>
-<center><math>t=4m^2-4m^2+ 4p \ ^{*2})</math></center>
+<center><math>t_{max}=4m^2-4m^2- 4p \ ^{*2}</math></center>
-<center><math>t=4p \ ^{*2}</math></center>
+The maximum transfer of momentum would be
-<center><math>-2 p \ ^{*2}(1-cos\ \theta)=4p \ ^{*2}</math></center>
+<center><math>t_{max}=-4p \ ^{*2}</math></center>
-<center><math>(1-cos\ \theta)=-2</math></center>
+<center><math>-2 p \ ^{*2}(1-cos\ \theta_{t=max})=-4p \ ^{*2}</math></center>
-<center><math>-cos\ \theta=-3</math></center>
+<center><math>(1-cos\ \theta_{t=max})=2</math></center>
-<center><math> \theta_{max} \equiv \arccos 3</math></center>
+<center><math>-cos\ \theta_{t=max}=1</math></center>
-The domain of the arccos function is from −1 to +1 inclusive and the range is from 0 to π radians inclusive (or from 0° to 180°).  This implies for arccos 3, the range will include imaginary numbers.  Knowing that the range of the cosine function is -1 to +1 inclusive and the domain to be any angle
-<center><math>\theta = \arccos{3}</math></center>
+<center><math> \theta_{t=max} \equiv \arccos -1</math></center>
-<center><math>\cos{\theta} = \cos{\arccos{3}}</math></center>
+The domain of the arccos function is from −1 to +1 inclusive and the range is from 0 to π radians inclusive (or from 0° to 180°).  We find as expected for u=0 at <math>\theta=180^{\circ}</math>
+<center><math>\theta_{t=max}=180^{\circ}</math></center>
-<center><math>\cos{\theta} = 3</math></center>
+However, from the definition of s being invariant between frames of reference
-From Euler's formula
+<center><math>s \equiv \overbrace{\left({\mathbf P_1^*}+ {\mathbf P_2^{*}}\right)^2=\left({\mathbf P_1^{'*}}+ {\mathbf P_2^{'*}}\right)^2}^{CM\ FRAME}=\overbrace{\left({\mathbf P_1}+ {\mathbf P_2}\right)^2 = \left({\mathbf P_1^{'}}+ {\mathbf P_2^{'}}\right)^2}^{LAB\ FRAME}</math></center>
-<center><math>\cos{x} = \frac{e^{i \theta} + e^{-i \theta}}{2}</math></center>
+In the center of mass frame of reference,
+<center><math>E_1^*=E_2^*=E^* \quad and \quad \vec p \ _1^*=-\vec p \ _2^*= \vec p \ ^*</math></center>
-<center><math> \frac{e^{i \theta} + e^{-i \theta}}{2} = 3</math></center>
+<center><math>s \equiv 2m^2+2(E_1^{*2}+\vec p \ ^{*2} )</math></center>
-<center><math> e^{i \theta} + e^{-i \theta} = 6</math></center>
+Using the relativistic energy equation
-Multiply with <math>e^{i \theta}</math>
+<center><math>E^2 \equiv \vec p \ ^2+m^2</math></center>
-<center><math>e^{2i \theta} + 1 = 6e^{i \theta}</math></center>
+<center><math>s \equiv 2m^2+2((m^2+\vec p \ ^{*2})+\vec p \ ^{*2})</math></center>
-<center>Letting <math>y = e^{i \theta}</math></center>
+<center><math>s=4m^2+4 \vec p \ ^{*2})</math></center>
-We get an quadratic equation:
+<center><math>\frac{s-4m^2}{4}= \vec p \ ^{*2}</math></center>
-<center><math>y^2 - 6y + 1 = 0</math></center>
-<center><math>y = (6 ± √32)/2</math></center>
+<center><math>t=-2 p \ ^{*2}(1-cos\ \theta)=\frac{-2(s-4m^2)}{4}(1-cos\ \theta)</math></center>
-<center><math>y_1 = 5.828427 = e^{i \theta}</math></center>
+<center><math>\frac{-2t}{s-4m^2}=(1-cos\ \theta)</math></center>
-<center><math>y_2 = 0.171573 = e^{i \theta}</math></center>
+<center><math>cos\ \theta=1-\frac{-2t}{s-4m^2}</math></center>
-Apply ln on both sides gives the solution for arccos 3:
+----
-<center><math>\theta_1 = \frac{ln(5.828427) }{ i}=-1.76275i</math></center>
+<center><math>\underline{\textbf{Navigation}}</math>
+[[U-Channel|<math>\vartriangleleft </math>]]
+[[VanWasshenova_Thesis#Moller_Scattering|<math>\triangle </math>]]
+[[Limit_of_Energy_in_Lab_Frame|<math>\vartriangleright </math>]]
-<center><math> \theta_2 = \frac{ln(0.171573) }{ i}=1.76275i</math></center>
+</center>

Difference between revisions of "Limits based on Mandelstam Variables"

Latest revision as of 19:07, 1 January 2019

Limits based on Mandelstam Variables

Navigation menu

Search