Difference between revisions of "TF DerivationOfCoulombForce"

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If you measure the phase shift you can determine "sign" of V.
 
If you measure the phase shift you can determine "sign" of V.
  
Cross-section:<math> \frac{d \sigma}{d \omega} =</math> differential X-section = <math>\frac{\frac{# scattered}{solid-angle}}{\frac{#in}{Area}}</math>
+
Cross-section:<math> \frac{d \sigma}{d \Omega} =</math> differential X-section = <math>\frac{\frac{# scattered}{solid-angle}}{\frac{#in}{Area}}</math>

Revision as of 22:37, 2 March 2009

Poisson's Equation
[math]\nabla^2 \phi(\vec{\xi}) = - \frac{\rho}{\epsilon_0} =- \frac{e}{\epsilon_0} \delta(\vec{\xi})[/math]

Fourier Transform of Poisson's Equation

[math]\frac{1}{(2 \pi)^{3/2}} \int e^{-i \vec{k} \cdot \vec{\xi}} \nabla^2 \phi(\vec{\xi})dV = - \frac{1}{(2 \pi)^{3/2}} \frac{e}{\epsilon_0} \int e^{-i \vec{k} \cdot \vec{\xi}}\delta(\vec{\xi}) dV [/math]
[math]\frac{1}{(2 \pi)^{3/2}} \int e^{-i \vec{k} \cdot \vec{\xi}} \vec{\nabla} \cdot (\vec{\nabla} \phi(\vec{\xi}))dV = - \frac{e}{(2 \pi)^{3/2}\epsilon_0} (1)[/math]

Product rule for dervatives

[math]\frac{1}{(2 \pi)^{3/2}} \int \left \{ \vec{\nabla} \cdot ( e^{-i \vec{k} \cdot \vec{\xi}} \vec{\nabla} \phi ) - (\vec{\nabla} e^{-i \vec{k} \cdot \vec{\xi}}) \cdot (\vec{\nabla} \phi) \right \} dV = - \frac{e}{(2 \pi)^{3/2}\epsilon_0} (1)[/math]


Gauss' Theorem:

[math]\int \vec{\nabla} \cdot ( e^{-i \vec{k} \cdot \vec{\xi}} \vec{\nabla} \phi ) dV = \oint_S e^{-i \vec{k}\cdot \vec{\xi}} \vec{\nabla}\cdot d\vec{A}[/math]


Definition of derivative:

[math](\vec{\nabla} e^{-i \vec{k} \cdot \vec{\xi}}) \cdot (\vec{\nabla} \phi ) = \vec{\nabla} \cdot (\phi \vec{\nabla} e^{-i \vec{k}}) - \phi {\nabla}^2 e^{-i \vec{k} \cdot \vec{\xi}}[/math]


Substituting

[math]\frac{1}{(2 \pi)^{3/2} } \left \{ \oint_S e^{-i \vec{k} \cdot \vec{\xi}} \vec{\nabla} \phi \cdot d\vec{A} - \int \vec{\nabla} \cdot (\phi \vec{\nabla} e^{-i \vec{k} \cdot \vec{\xi}} ) dV + \int \phi {\nabla}^2 e^{-i \vec{k} \cdot \vec{\xi}} dV \right \} = \frac{-e}{(2 \pi)^{3/2} \epsilon_0}[/math]


Gauss' Low:

[math]\int \vec{\nabla}\cdot (\phi \vec{\nabla} e^{-i \vec{k} \cdot \vec{\xi}} ) dV = \oint_S \phi \vec{\nabla} e^{-i k \xi } \cdot d\vec{A}[/math]


[math]\frac{1}{(2 \pi)^{3/2} } \left \{\oint_S \left \{ e^{-i \vec{k} \cdot \vec{\xi}} \vec{\nabla} \phi - \phi \vec{\nabla} e^{-i \vec{k} \cdot \vec{\xi}} \right \} \cdot d\vec{A} + \int \phi {\nabla}^2 e^{-i \vec{k} \cdot \vec{\xi}} dV \right \} = \frac{-e}{(2 \pi)^{3/2} \epsilon_0}[/math]


[math]\frac{1}{(2 \pi)^{3/2} } \int \phi (-ik) (-ik) e^{-i \vec{k} \cdot \vec{\xi}} dV = \frac{-e}{(2 \pi)^{3/2} \epsilon_0}[/math]


[math]-k^2 \frac{1}{(2 \pi)^{3/2} } \int \phi(\xi) e^{-i \vec{k} \cdot \vec{\xi}} dV_{xi} = \frac{-e}{(2 \pi)^{3/2} \epsilon_0}[/math]

[math]-k^2 \phi(k) = \frac{-e}{(2 \pi)^{3/2} \epsilon_0}[/math]

1.) Coulomb [math]\phi(k) = \frac{e}{(2 \pi)^{3/2} \epsilon_0} \frac{1}{k^2}[/math] = potential in "k"(momentum) space

To find the potential in "coordinate" [math](\xi)[/math] space just inverse transform

[math]\phi (\xi) = \frac{1}{(2 \pi)^{3/2} } \int e^{+ i \vec{k} \cdot \vec{\xi}} \phi (k) dV_k[/math]
[math]= \frac{1}{(2 \pi)^{3/2} } \int e^{i \vec{k} \cdot \vec{\xi}} \frac{e}{2 \pi)^{3/2} \epsilon_0} \frac{1}{k^2} dV_k[/math]
[math]= \frac{e}{(2 \pi)^{3} \epsilon_0} \int \frac{e^{i \vec{k} \cdot \vec{\xi}}}{k^2} dV_k[/math]


[math]dV_k=k^2 sin{\theta}_k d{\theta}_k d{\phi}_k dk[/math]


[math]=\frac{e}{(2 \pi)^{3} \epsilon_0} {{\int}_0}^{2\pi} d{\phi}_k {{\int}_0}^{\pi} d{\theta}_k {{\int}_0}^{\infty} dk \times k^2 sin{\theta}_k e^{i \vec{k} \cdot \vec{\xi}}[/math]
[math]=\frac{e}{(2\pi)^2 \epsilon_0} {{\int}_0}^{\pi} {{\int}_0}^{\infty} sin{\theta}_k e^{ik \xi cos{\theta}_k} k^2 dk[/math]

[math]u=cos\theta[/math]

[math]du=sin\theta d\theta[/math]


[math]\phi(\xi) = \frac{e}{4 {\pi}^2 \epsilon_0} {{\int}_0}^infty {{\int}_{-1}}^1 \frac{e^{ik\xi u}}{k^2} du k^2 dk[/math]
[math]=\frac{e}{4 {\pi}^2 \epsilon_0} {{\int}_0}^infty \frac{e^{ik \xi} - e^{-ik\xi}}{ik\xi} dk[/math]
[math]=\frac{e}{4 {\pi}^2 \epsilon_0} \frac{1}{i\xi} (i\pi) = \frac{e}{4 {\pi}^2 \epsilon_0} \frac{1}{\xi}[/math]
[math]=\frac{e}{4 {\pi}^2 \epsilon_0} \frac{1}{|\vec{r} - \vec{r}^'|} =[/math] Coulomb potential
2) Nuclear potential

Consider the force field generated by a point source (nucleon) at location [math]\vec{r}[/math] from the origin of a coordinate system.

300px

Assume a particle of mass m is e charged to generate the field (In Coulomb force particle was m=o photon).

Definition of relativistic Energy:

[math]E^2=(mc^2)^2 + (cp)^2[/math]

In terms of Hamiltonian

[math]-\hbar \frac{d^2}{dt^2} \phi(\vec{r}) = [ (mc^2)^2 + (\frac{c\hbar \vec{\nabla}}{i})^2 ] \phi (r)[/math]


In a static case

[math][(mc^2)^2 - c^2 {\hbar}^2 {\nabla}^2]\phi(r)=0[/math]

[math][ {\nabla}^2 - (\frac{mc}{\hbar})^2]\phi(r)=0[/math]

Lets [math]\mu = \frac{mc}{\hbar} = \frac{(140 \frac{MeV}{c^2})c}{6.6 \times 10^{-16}eV \cdot s} (\frac{10^6 eV}{MeV})[/math]

[math]=\frac{2.1 \times 10^23}{(3\times 10^8 m)} (\frac{10^{-15}m}{fm}) =\frac{0.7}{fm} (200 MeV fm) = 140 MeV[/math]


[math]\hbar c=(6.6 \times 10^{-16} eV \cdot s) (3 \times 10^8 \frac{m}{s}) (\frac{10^{15} fm}{m}) (\frac{1 MeV}{10^6 eV}) = 198 MeV \cdot fm \approx 200 MeV \cdot fm[/math]
[math]\mu = \frac{mc^2}{\hbar c} = \frac{mc^2}{200 MeV \cdot fm}[/math] [math]\Longrightarrow[/math] if [math]mc^2\approx 200 MeV[/math] then interaction length [math]\sim 1 fm[/math].


With the source term

[math][{\nabla}^2 - {\mu}^2]\phi(\xi) = -{{\xi}_0}^' \delta(\xi)[/math]

As seen before for Coulomb force


[math]\frac{1}{(2\pi)^{3/2}} \int e^{-ik \xi} [{\nabla}^2 - {\mu}^2] \phi (\xi) dV = -\frac{{{\xi}_0}^'}{(2\pi)^{3/2}} \int e^{-i \vec{k} \cdot \vec{\xi}} \delta (\xi) dV[/math]
[math][-k^2 -{\mu}^2]\phi(\vec{k}) = -\frac{{{\xi}_0}^'}{(2\pi)^{3/2}}[/math]
[math]\Longrightarrow \phi(\vec{k}) = \frac{{{\xi}_0}^'}{(2\pi)^{3/2}} \frac{1}{k^2 + {\mu}^2}[/math]
[math]\phi(\vec{\xi}) = \frac{1}{(2 \pi)^{3/2}} \int \frac{e^{+i \vec{k} \cdot \vec{\xi}}}{(2 \pi)^{3/2}} \frac{{{\xi}_0}^'}{k^2 + {\mu}^2} dV_k[/math] : inverse fourier transform
[math]= \frac{{{\xi}_0}^'}{(2\pi)^3} \int \frac{e^{+i \vec{k} \cdot \vec{\xi}}}{k^2 + {\mu}^2} k^2 sin\theta d\theta d\phi dk[/math]
[math]\phi(\xi) = \frac{{{\xi}_0}^'}{(2\pi)^2} \int \frac{e^{i\vec{k} \cdot \vec{\xi}}}{(k^2 + {\mu}^2)} k^2 d[cos\theta] (2\pi) dk[/math]
[math]= \frac{{{\xi}_0}^'}{(2\pi)^2} {{\int}_0}^{\infty} \frac{k^2}{k^2 + {\mu}^2} {{\int}_0}^{\pi} e^{ik\xi cos\theta} d[cos\theta] dk[/math]
[math]= \frac{{{\xi}_0}^'}{(2\pi)^2} {{\int}_0}^{\infty} \frac{k^2}{k^2 + {\mu}^2} dk \frac{e^{ik\xi \mu}}{ik\xi} {|_{-1}}^1[/math]
[math]= \frac{{{\xi}_0}^'}{(2\pi)^2} \frac{1}{i\xi} {{\int}_0}^{\infty} \frac{k}{k^2 + {\mu}^2} (e^{ik\xi} - e^{-ik\xi})[/math]
[math]= \frac{{{\xi}_0}^'}{(2\pi)^2}\frac{1}{i\xi} {{\int}_{-\infty}}^{\infty} \frac{e^{ik\xi}kdk}{k^2 + {\mu}^2}[/math]
[math]{{\int}_{-\infty}}^{\infty} \frac{e^{ik\xi}kdk}{k + i{\mu}}{k - i{\mu}} = i\pi e^{-\mu \xi}[/math]
[math]\phi(\xi) = \frac{{{\xi}_0}^'}{(2\pi)^2} \frac{e^{-\mu \xi}}{\xi}[/math]

[math]\Longrightarrow[/math]

[math]\phi(\vec{r}) = \frac{{{\xi}_0}^'}{(2\pi)^2} \frac{1}{|\vec{r} - {\vec{r}}^'|}[/math]
[math]{\phi}_{EM}(\vec{r}) = \frac{e}{4\pi \epsilon_0} \frac{1}{|\vec{r} - {\vec{r}}^'|}[/math]

Coupling constants are:

??????????????????????????????????
??????????????????????????????????


Summary

There are now at least two forces which act between Nucleons, the Coulomb force and the Nucleon force. We can write the force in terms of a potential

[math]V_{EM} = \frac{e}{4\pi \epsilon_0} \frac{1}{|\vec{r} - {\vec{r}}^'|}[/math]


[math]V_{Nuc} = \frac{{{\xi}_0}^'}{(2\pi)^2} \frac{e^{-\mu |\vec{r} - {\vec{r}}^'|}}{|\vec{r} - {\vec{r}}^'|}[/math]
[math]V_{tot} = \frac{1}{4\pi} \left \{ \frac{Q_1 Q_2}{\epsilon_0 e } - \frac{{\xi}_0}{\pi} e^{-\mu |\vec{r} - {\vec{r}}^'|} \right \} \frac{1}{|\vec{r} - {\vec{r}}^'|}[/math]
[math]\mu=\frac{m_{\pi}c}{\hbar}=\frac{1}{R} \sim (1.5 fm)^{-1}[/math]
C.) Deuteron
[math]({H_1}^2)[/math], [math](D^2)[/math], (d) = a proton-neutron bound state

General properties: L=0 - orbital angular momentum

[math]J^{\pi} = 1^+[/math] - (Nuclear spin)

[math]\sqrt{r^2}=2.095 fm[/math] - Mean radius.

[math]B.E.=2.2246 MeV[/math] - Binding energy.

Non-relativistic Schrodiger solution
[math]B.E. = 2.2246 MeV \lt \lt 1.8 GeV m(H^2)c^2[/math]

[math]\Longrightarrow[/math] weakly bound system

Instead of Dirac equation try 3-D Square Well Schrod. Eq. approximation for Deuteron wavefunction.

350px

[math]V(r) = -V_0[/math] when [math]r \leq R = 2.2[/math]

[math]V(r) = 0[/math] [math]r\gt R[/math]

Assume [math]\psi = Y_{00} \frac{V(r)}{r}[/math] : No angular dependence, only radial dependence.

Schrod. Equation

[math]-\frac{\hbar^2}{2m} {\nabla}^2 \psi + V(r)\psi = E \psi[/math]

[math]{\nabla}^2 = \frac{1}{r^2} \frac{\partial}{\partial r}(r^2 \frac{\partial}{\partial r}) + \frac{1}{r^2 sin\theta} \frac{\partial}{\partial \theta} (sin\theta \frac{\partial}{\partial \theta}) + \frac{1}{r^2 sin^2 \theta} \frac{{\partial}^2}{\partial {\phi}^2} [/math]


[math]-\frac{\hbar^2}{2m} Y_{00} \frac{1}{r^2} \frac{\partial}{\partial r} r^2 \frac{\partial (U(r)/r)}{\partial r} + \frac{1}{r^2 sin\theta}\frac{U(r)}{r}(\frac{\partial}{\partial \theta} sin \theta \frac{\partial Y_{00}}{\partial \theta})[/math]

[math]+ \frac{U(r)}{r^3 sin^2 \theta} \frac{{\partial}^2}{\partial {\phi}^2} Y_{00} + \frac{V(r)Y_{00} U(r)}{r} = \frac{E U(r)}{r}[/math]


[math]\frac{1}{r^2} \frac{\partial}{\partial r} r^2 \frac{\partial}{\partial r} \frac{U(r)}{r} = \frac{1}{r^2} \frac{\partial}{\partial r} r^2 [\frac{1}{r}\frac{\partial U(r)}{r} - \frac{U(r)}{r^2}][/math]

[math]= \frac{1}{r^2} [\frac{\partial U(r)}{\partial r} + r \frac{\partial^2 U(r)}{\partial r^2} - \frac{2rU(r)}{r^2} - \frac{r^2}{r^2} \frac{\partial U(r)}{\partial r} - r^2 U(r)\frac{-2}{r^3}][/math]

[math]= \frac{1}{r}\frac{\partial^2 U(r)}{\partial r^2} + \frac{1}{r^2} \frac{\partial U(r)}{\partial r} - \frac{1}{r^2} \frac{\partial U(r)}{\partial r} - \frac{2U(r)}{r^2} + \frac{2U(r)}{r^2}[/math]

[math]= \frac{1}{r}\frac{\partial^2 U(r)}{\partial r^2}[/math]


[math]\frac{U(r)}{r^3 sin\theta}(\frac{\partial}{\partial \theta} sin\theta \frac{\partial}{\partial \theta})Y_{00} = \frac{U(r)}{r^3 sin\theta} l(l+1)Y_{00}[/math]

[math]=\frac{U(r)}{r^3 sin\theta}[\frac{\partial}{\partial \theta} sin\theta \frac{\partial}{\partial \theta}]\frac{1}{\sqrt{4\pi}}=0[/math]


[math]\frac{U(r)}{r^3 sin\theta} \frac{\partial^2}{\partial {\phi}^2} Y_{00} = 0[/math] : [math]Y_{00} = \frac{1}{\sqrt{4\pi}}[/math]

Schrod. Equation becomes

[math]-\frac{\hbar^2}{2m} \frac{Y_{00}}{r} \frac{\partial^2 U(r)}{\partial r^2} + V(r) Y_{00}\frac{U(r)}{r} = E \frac{U(r)Y_{00}}{r}[/math]


[math] \Longrightarrow[/math] for [math]r\leq R[/math] : [math] V(r)= -V_0[/math]


[math]\frac{\partial^2 U(r)}{\partial r^2} + \frac{2m}{\hbar^2}(E+V)U(r) = 0[/math]

for [math]r\gt R[/math] : [math]V(r)=0[/math]


[math]\frac{\partial^2 U(r)}{\partial r^2} + \frac{2m}{\hbar^2} E U(r) = 0[/math]


File:ImageTF 1.jpg

[math]\psi_{I}[/math]

[math] \frac{\partial^2 U_I (r)}{\partial r^2} + {k_1}^2 U(r) = 0[/math] : [math] {k_1}^2 = \frac{2m}{\hbar^2}(E + V)[/math]

[math] \Longrightarrow[/math] [math]U_I (r) = A sin(k_1 r) + Bcos(k_1 r)[/math] : spring simple harmonic motion


Boundary condition:

[math]\psi_I (r=0)=0[/math] [math]\Longrightarrow[/math] [math]B=0[/math]
[math]\psi_{II}[/math]

[math]\frac{\partial^2 U_{II} (r)}{\partial r^2} + {k_2}^2 U(r) = 0[/math] : [math] {k_2}^2 = \frac{2m}{\hbar^2} E \lt 0[/math]

E<0 for bound states. Taking out " - " sign in [math]{k_2}^2[/math]

[math]\frac{\partial^2 U_{II} (r)}{\partial r^2} - {k_2}^2 U(r) = 0[/math]

New definition of [math]{k_2}^2[/math] : [math]{k_2}^2=\frac{2m}{\hbar^2}|E|[/math]

[math]\Longrightarrow[/math] [math]U_{II}(r) = C e^{-k_2 r} + D e^{k_2 r}[/math]


Boundary condition:[math] U_{II} (r=\infty)[/math] - finite [math]\Longrightarrow[/math] D=0


[math]U_I (r) = A sin(k_1 r)[/math]

[math]U_{II} (r) = C e^{-k_2 r}[/math]

Bounding condition

[math]U_I (r=R) = U_{II} (r=R)[/math]

[math]\frac{\partial U_I}{\partial r} {\mid}_{r=R} = \frac{\partial U_{II}}{\partial r} {\mid}_{r=R}[/math]

[math]\Longrightarrow[/math] [math]A sin(k_1 R) = C e^{-k_2 R}[/math]

[math]A k_1 cos(k_1 R) = -C k_2 e^{-k_2 R}[/math]

Dividing two equations [math]\Longrightarrow[/math]

[math]\frac{tan(k_1 R)}{k_1} = - \frac{1}{k_2}[/math]

[math]\Longrightarrow[/math] [math]tan(k_1 R) = - \frac{k_1}{k_2} = -\sqrt{\frac{\frac{2m}{\hbar^2}(V + E)}{\frac{2m}{\hbar^2}|E|}}[/math]

But E<0 for bound states

[math]tan(k_1 R) = - \sqrt{\frac{(V - |E|)}{|E|}} = -X = -\frac{k_1}{k_2}[/math]


[math]k_1 R = X k_2 R = X\beta[/math]

[math]-X = tan (\beta X)[/math]

Solving the ??? 59 eqution:

[math]X=-tan(\beta X)[/math]

[math]\beta X = k_1 R[/math] [math]\Longrightarrow[/math] [math]\beta = \frac{k_1}{X}R = k_2 R = \sqrt{\frac{2m|E|}{\hbar^2}} R[/math]

m = reduced mass

[math]\beta = \sqrt{\frac{2(\frac{938.98}{2} MeV) |E|}{(\hbar c)^2}} R[/math] :


[math]:=\sqrt{\frac{(938.98) MeV (2.224 MeV)}{ (197.3 \cdot MeV \cdot fm)^2}} R[/math]
[math]=\sqrt{\frac{(938.98) \cdot (2.224) MeV^2}{(197.3)^2 MeV^2 \cdot fm^2}} (2.095 fm)[/math]
[math]= 0.4853[/math]

[math]|E| = |-2.224 MeV|[/math]

Find X s.t. [math]X = -tan (0.4853 X)[/math]

Using ?? 59 of graphing [math]\Longrightarrow[/math] [math]X=3.91 = \frac{k_1}{k_2}[/math]

[math]k_2 = \sqrt{\frac{2m |E|}{\hbar^2}} = \frac{\beta}{R} = \frac{0.9853}{2.095 \cdot fm} = \frac{1}{fm}[/math]

[math]k_1 = X k_2 = (3.931) (\frac{0.231}{fm}) = \frac{0.91}{fm} = \sqrt{\frac{2m (V - |E|)}{\hbar^2}}[/math]

[math]V_0 = 36 MeV[/math]

Spin and Parity
[math](I^{\pi})[/math]


66-78 pages

The shrodinger equation for this scattering:

[math]-\frac{\hbar^2}{2m} \nabla^2 \psi + \nabla \psi = E \psi[/math]

In spherical coordinates this may be written as:

Let [math] \psi = \frac{U_l (r) Y_{lm}(\theta, \phi)}{r} [/math]
[math]-\frac{\hbar^2}{2m} \frac{\partial^2 U_l (r)}{\partial r^2} + \frac{l(l+1) \hbar}{2m} \frac{U_l (r)}{r^2} + V U_l(r) = E U_l (r)[/math]

or

[math]-\frac{\hbar^2}{2m} \frac{\partial^2 U_l (r)}{\partial r^2} + ( V + \frac{l(l+1) \hbar^2}{2m} \frac{1}{r^2}) U_l (r) = E U_l(r)[/math]

General solution:

[math]\frac{U_l(r)}{r} = A_l J_l (kr) + B_l N_l (kr)[/math]

where

[math]J_l(kr)[/math] = Bessel function
[math]N_l(kr)[/math] = Neiman function

1.) Distant scattering: r is large such that neutron "glances" off.

[math]J_l (kr) \approx \frac{sin(kr - l \pi /2)}{kr}[/math]
[math]N_l (kr) \approx - \frac{cos (kr - l\pi /2)}{kr}[/math]
[math]\Longrightarrow[/math] [math]\frac{U_l(r)}{r} = \frac{A_l sin(kr - \frac{l \pi}{2}) - B_l cos(kr - \frac{l \pi}{2})}{kr}[/math]


[math]\frac{\psi_I (r)}{r} = A_{lI} \frac{sin(k_I r - \frac{l \pi}{2})}{k_I r}[/math]
[math]k_I = \sqrt{\frac{2m (V + E)}{\hbar^2}}[/math]
[math]U_I (r=0)[/math] = finite, no cosine term.
[math]\frac{U_{II}(r)}{r} = A_{l II} \frac{sin(k_{II}r - l \pi /2)}{k_{II}r} - B_{l II} \frac{cos(k_{II}r - l \pi /2)}{k_{II}r}[/math]
[math]k_{II} = \sqrt{\frac{2mE}{\hbar^2}}[/math]

Normalizing and simplifying [math]U_{II}(r)[/math]

[math]\frac{U_{II}(r)}{r} = \sqrt{{A_{l II }}^2 + {B_{l II}}^2} [ \frac{A_{l II}}{\sqrt{{A_{l\pi}}^2 + {B_{l II}}^2}} \frac{sin(k_{II}r - l \pi /2)}{k_{II}r} - \frac{B_{l II}}{\sqrt{{A_{l II}}^2 + {B_{l II}}^2}} \frac{cos(k_{II}r - l \pi /2)}{k_{II}r} ] [/math]


[math]cos (\delta_l) = \frac{A_{l II}}{\sqrt{{A_{l II}}^2 + {B_{l II}}^2}}[/math]
[math]sin (\delta_l) = \frac{B_{l II}}{\sqrt{{A_{l II}}^2 + {B_{l II}}^2}}[/math]

[math]\Longrightarrow[/math]

[math]\frac{U_{II}(r)}{r} = \frac{\sqrt{{A_{l II}}^2 + {B_{l II}}^2}}{k_{II}r} \left \{ cos (\delta_l) sin(k_{II}r - l \pi /2) + sin ( \delta_l)cos(k_{II}r - l \pi /2) \right \} [/math]

[math]+/- cosA sinB + sinA cosB = sin(A +/- B)[/math]

[math]\frac{U_{II}(r)}{r} = \frac{\sqrt{{A_{l II}}^2 + {B_{l II}}^2}}{k_{II}r} sin (k_{II} r - l \pi /2 + \delta_l)[/math]
[math]=C_l \frac{sin(k_{II} r - l \pi /2 + \delta_l)}{k_{II}r}[/math]

[math]A_{l II}[/math] and [math]C_l[/math] are found by applying Boundary conditions:

[math]\psi_I (r=R) = \psi_{II} (r=R)[/math]
[math]\frac{\partial \psi_I}{\partial r} \mid_{r=R} = \frac{\partial \psi_{II}}{\partial r} \mid_{r=R}[/math]
Example
l=0 special case
[math]\psi = \frac{U_l (r)}{r} Y_{lm}(\theta, \phi)[/math] [math]\Longrightarrow[/math] [math]\psi_{l=0} = \frac{U(r)}{r}[/math]
[math]\frac{U_I (r)}{r} = A_I \frac{sin(k_I r - 0 \pi /2)}{k_I r}[/math]
[math]{k_I}^2 = \frac{2m(V + E)}{\hbar^2}[/math]
[math]\frac{U_{II} (r)}{r} = C \frac{sin(k_{II} r - 0 \pi /2 + \delta_0)}{k_{II} r}[/math]
[math]k_{II}^2 = \frac{2m E}{\hbar^2}[/math]


Apply Boundary Conditions:

[math]U_I (r=R) = U_{II} (r=R)[/math]
[math]A_I sin(k_I R) = C sin(k_{II} R + \delta_0)[/math]
[math]\frac{\partial \psi_I}{\partial r} \mid_{r=R} = \frac{\partial \psi_{II}}{\partial r} \mid_{r=R}[/math]
[math]A_I k_I cos(k_I R) = C k_{II} cos(k_{II} R + \delta)[/math]

[math]k_I[/math], [math]k_{II}[/math] and R are known. [math]\delta[/math] is unknown.

[math]\frac{U_I (R)}{ \frac{\partial U_I (r)}{\partial r} } = \frac{U_{II} (R)}{ \frac{\partial U_{II] (r)}{\partial r} }[/math]

[math]\Longrightarrow[/math]

[math]k_I cot(k_I R) = k_{II} cot (k_{II} R + \delta)[/math]
[math]k_{II}^2 = \frac{2m E}{\hbar^2}[/math]
[math]k_{II}^2 = \frac{2m E}{\hbar^2}[/math]

If V=0 [math]\Longrightarrow[/math] [math]k_I = k_{II}[/math] [math]\Longrightarrow[/math] [math]\delta = 0[/math]: Free neutron; No target; No phase shift.

image70_1


If V>0 [math]\Longrightarrow[/math] [math]k_I \gt k_{II}[/math]:

image70

If V<0 [math]\Longrightarrow[/math] [math]k_I \lt k_{II}[/math] [math]\Longrightarrow[/math] [math]\delta \lt 0[/math]: E>0; Neutron not bound.

If you measure the phase shift you can determine "sign" of V.

Cross-section:[math] \frac{d \sigma}{d \Omega} =[/math] differential X-section = [math]\frac{\frac{# scattered}{solid-angle}}{\frac{#in}{Area}}[/math]