Integrated yields

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Latest revision as of 13:40, 15 June 2011 (view source)

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(separated p-gamma event calculation into a new subsection)

Line 14:

After an integration, the cross section in mb is obtained by multiplying the yield by

-

the Ge solid angle in <math>sr</math> and dividing by the target thickness in <math>mg/cm^2</math>. ~~You can also calculate the absolute~~

+

the Ge solid angle in <math>sr</math> and dividing by the target thickness in <math>mg/cm^2</math>.

-

~~p-gamma counts expected using the equation following equation 6.44b in the manual:~~

+

-

Detected p-gamma coincident events

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===Detected p-gamma coincident events===

+

The absolute p-gamma counts expected can be calculated using the equation following equation 6.44b in the manual:

<math>N_i = 10^{-30} [Q / qe] [N_A / A] Y(I_i-->I_f) \epsilon_p \epsilon_\gamma \Delta \Omega_\gamma</math>, (1)

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where <math>Q</math> is the integrated beam current incident on the target during the experiment, <math>q</math> is the average charge state of the beam, <math>e</math> is the electron charge,

-

If the absolute efficiency is known well, then it is possible to ~~retrieve~~

+

If the absolute efficiency is known well, then it is possible to reproduce

the actual counts measured in the photopeak by putting the efficiency into this

equation.

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Refer to the page on the [[particle_singles | particle singles]], which is a cross section given in the same output with the integrated yields.

+

==Representing a <math>4\pi</math> Array in Gosia==

-

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A <math>4\pi</math> array can be represented in Gosia in a single calculation without summing the output of a large number of detectors. See the page on [[four_pi_arrays | 4pi arrays]].

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~~==Quickly representing a summed 4pi array==~~

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-

+

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~~Gosia can quickly integrate the p-<math>\gamma</math> events over a~~ <math>4\pi</math> Ge array ~~without adding a detector at every laboratory position. In order to do this, the output file 9~~ can be ~~modified to make the first two attenuation coefficients 0 for all orders. (File 9 is~~ the output of ~~OP,GDET, commonly called the *.gdt file. For Gammasphere the *.gdt file would look something like~~

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+

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~~<pre>~~

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1

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~~25.0~~

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~~5.000E-02~~

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~~0. 0. 0.9951~~

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~~0. 0. 0.9854~~

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~~0. 0. 0.9711~~

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~~0. 0. 0.9521~~

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~~0. 0. 0.9379~~

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~~0. 0. 0.9013~~

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~~0. 0. 0.8699~~

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~~0. 0. 0.8349~~

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~~</pre>~~

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-

+

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~~where the first two columns have been set to 0. to simulate~~ a ~~4pi array~~. ~~In this case the <math>\epsilon_\gamma</math> value would~~

+

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~~still be the absolute photopeak efficiency, but <math>\Delta\Omega_\gamma</math> would be 4*pi.~~

+

-

+

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See the ~~manual entries~~ on ~~OP,GDET and "Gamma Detector Solid Angle Attenuation Factors" for more information on these attenuation coefficients~~.

+

Integrated yields

From GOSIA

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@@ Line 14: / Line 14: @@
 After an integration, the cross section in mb is obtained by multiplying the yield by
-the Ge solid angle in <math>sr</math> and dividing by the target thickness in <math>mg/cm^2</math>.  You can also calculate the absolute
+the Ge solid angle in <math>sr</math> and dividing by the target thickness in <math>mg/cm^2</math>.
-p-gamma counts expected using the equation following equation 6.44b in the manual:
-Detected p-gamma coincident events
+===Detected p-gamma coincident events===
+The absolute p-gamma counts expected can be calculated using the equation following equation 6.44b in the manual:
 <math>N_i = 10^{-30} [Q / qe] [N_A / A] Y(I_i-->I_f) \epsilon_p \epsilon_\gamma \Delta \Omega_\gamma</math>, (1)
@@ Line 23: / Line 24: @@
 where <math>Q</math> is the integrated beam current incident on the target during the experiment, <math>q</math> is the average charge state of the beam, <math>e</math> is the electron charge,
-If the absolute efficiency is known well, then it is possible to retrieve
+If the absolute efficiency is known well, then it is possible to reproduce
 the actual counts measured in the photopeak by putting the efficiency into this
 equation.
@@ Line 41: / Line 42: @@
 Refer to the page on the [[particle_singles | particle singles]], which is a cross section given in the same output with the integrated yields.
+==Representing a <math>4\pi</math> Array in Gosia==
+A <math>4\pi</math> array can be represented in Gosia in a single calculation without summing the output of a large number of detectors.  See the page on [[four_pi_arrays | 4pi arrays]].
-==Quickly representing a summed 4pi array==
-Gosia can quickly integrate the p-<math>\gamma</math> events over a <math>4\pi</math> Ge array without adding a detector at every laboratory position.  In order to do this, the output file 9 can be modified to make the first two attenuation coefficients 0 for all orders.  (File 9 is the output of OP,GDET, commonly called the *.gdt file.  For Gammasphere the *.gdt file would look something like
-<pre>
-.0
-.000E-02
-.  0.  0.9951
-.  0.  0.9854
-.  0.  0.9711
-.  0.  0.9521
-.  0.  0.9379
-.  0.  0.9013
-.  0.  0.8699
-.  0.  0.8349
-</pre>
-where the first two columns have been set to 0. to simulate a 4pi array.  In this case the <math>\epsilon_\gamma</math> value would
-still be the absolute photopeak efficiency, but <math>\Delta\Omega_\gamma</math> would be 4*pi.
-See the manual entries on OP,GDET and "Gamma Detector Solid Angle Attenuation Factors" for more information on these attenuation coefficients.