Integrated yields

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Gosia calculates the complete excitation and decay process using OP,INTI (or OP,INTG)

-

including all feeding, internal conversion branches and angular distributions.

+

including all feeding, internal conversion branches and angular distributions. These calculations are referred to as ''integrations'' below.

The p-<math>\gamma</math> angular distribution is integrated over the target thickness and

-

the Ge solid angles, but the resulting "YIELD" is quoted in units of <math>mb (mg/cm^2) / sr</math>.

+

the Ge solid angles, but the resulting "YIELD" is quoted in units of <math>mb (mg/cm^2) / sr</math>, where sr represents the solid

+

angle subtended by the Ge. This leads to some common misunderstandings.

-

~~This leads to a common misunderstanding~~-~~-that Gosia~~

+

The quoted yields represent the absolute cross sections for the chosen particle scattered into the solid angle of the particle detector and the <math>\gamma</math>-ray emitted into the solid angle of the Ge crystal or array, whichever is defined by the user.

-

~~does almost everything~~. The reason for the confusion is in the units and two

+

-

factors--the target thickness and the Ge solid angle--that must be applied

+

The reason for the confusion is usually the units of the YIELD output and two

+

factors—the target thickness and the Ge solid angle—that often must be applied

after the integration.

-

~~The "yield" from gosia is in mb(mg/cm^2)/sr, where sr represents the solid~~

+

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

-

~~angle of the Ge. In the case of a raw detector, it should be the total solid~~

+

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

-

~~angle of all crystals in the raw cluster. So, after~~ an ~~OP,INTG or OP,INTI~~

+

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

-

~~calculation~~, the cross section in mb is obtained by multiplying the yield by

+

-

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

+

-

p-gamma counts expected using equation ~~after~~ 6.44b in the ~~most recent~~ manual ~~version~~:

+

-

Detected p-gamma coincident events Ni = 10^(-30)[Q/qe][N_A/A] Y(I-->I_f) epsilon_p ~~epsilon_gamma~~

+

Detected p-gamma coincident events <math>N_i = 10^(-30) [Q / qe] [N_A / A] Y(I_i-->I_f) \epsilon_p \epsilon_\gamma \Delta \Omega_\gamma</math>

-

~~DeltaOmega_gamma~~

+

-

If ~~your~~ absolute efficiency is known well, then ~~you should be able~~ to retrieve

+

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

-

the actual counts in the ~~peak, since you are~~ putting the efficiency into ~~the~~

+

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

equation.

-

In the equation above ~~and your equation (1),~~ the epsilon_gamma is the absolute

+

In the equation above the <math>epsilon_gamma</math> is the absolute

efficiency as a fraction between 0 and 1 (not including angular effects already

-

integrated in the "yield"). ~~I think~~ this ~~is properly~~ called ~~the intrinsic~~

+

integrated in the "yield"). Let this be called the absolute photopeak efficiency.

-

~~efficiency, but I always worry that people understand the terms differently. I~~

+

The <math>\Delta\Omega_gamma</math> term is the solid angle of the Ge detector. A typical absolute photopeak efficiency <math>\epsilon_\gamma<\math> is 10--15%. If the solid angle subtended by the crystal is ~0.1 sr, then for one crystal <math>\epsilon_\gamma \Delta\Omega_\gamma ~ 0.01<\math>.

-

~~would call it~~ the absolute photopeak efficiency~~, not efficiency per unit solid~~

+

-

~~angle, because the solid angle is in the yield~~ term ~~and Delta_Omega. The~~

+

-

~~DeltaOmega_gamma~~ is the solid angle of the ~~crystal or cluster~~. ~~I would expect~~

+

-

~~your~~ efficiency ~~epsilon_gamma to be~~ 10--15%. If ~~you have about 0.1 sr~~ solid

+

-

angle subtended by a crystal, then for one crystal epsilon_gamma *

+

-

~~DeltaOmega_gamma~~ ~ 0.01~~, and for a cluster of 4 ~0.04.~~

+

-

+

-

~~So you can see if the numbers match what you fit in the energy spectrum~~.

+

-

~~The answer to your first question, is~~ the ~~factor N_gamma_p only~~ the ~~sum below~~

+

If the laboratory setup and the EM matrix are accurately represented in the Gosia input, then the absolute counts can be obtained:

-

the ~~photo-peak~~, ~~is yes, as long as you are using~~ the ~~photopeak efficiency as I~~

+

-

~~mentioned above.~~

+

-

~~You definitely don't need any other corrections for the cascade in Gosia's~~

+

<pre>

-

~~"yield."~~

+

N

+

<\pre>

-

~~About~~ the ~~"singles," they are~~ the ~~latter: the total number of particles hitting~~

+

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

-

~~the detector. Gosia should reproduce this number using the "integrated~~

+

-

~~rutherford cross section~~," which ~~probably shouldn't be called "Rutherford,"~~

+

-

~~because it includes all the inelastic events. For the scattering kinematics,~~

+

-

~~Gosia assumes that the Q-value~~ is ~~the energy of the first excited state--state~~

+

-

#2 in ~~LEVE. You can change this using~~ the ~~CONT option NCM, if you think that~~

+

-

the ~~probability of that state is <<1, for example. In that case, you might~~

+

-

~~pick the ground state~~. ~~If you put~~

+

-

~~OP,STAR~~

-

~~OP,EXIT~~

-

~~in place of OP,YIEL, you can quickly see the probabilities of all states in the~~

-

~~excitation.~~

Maybe the answer to your last question is obvious now, but... I would not try

Integrated yields

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@@ Line 2: / Line 2: @@
 Gosia calculates the complete excitation and decay process using OP,INTI (or OP,INTG)
-including all feeding, internal conversion branches and angular distributions.
+including all feeding, internal conversion branches and angular distributions. These calculations are referred to as ''integrations'' below.
 The p-<math>\gamma</math> angular distribution is integrated over the target thickness and
-the Ge solid angles, but the resulting "YIELD" is quoted in units of <math>mb (mg/cm^2) / sr</math>.
+the Ge solid angles, but the resulting "YIELD" is quoted in units of <math>mb (mg/cm^2) / sr</math>, where sr represents the solid
+angle subtended by the Ge.  This leads to some common misunderstandings.
-This leads to  a common misunderstanding--that Gosia
+The quoted yields represent the absolute cross sections for the chosen particle scattered into the solid angle of the particle detector and the <math>\gamma</math>-ray emitted into the solid angle of the Ge crystal or array, whichever is defined by the user.
-does almost everything.  The reason for the confusion is in the units and two
-factors--the target thickness and the Ge solid angle--that must be applied
+The reason for the confusion is usually the units of the YIELD output and two
+factors&mdash;the target thickness and the Ge solid angle&mdash;that often must be applied
 after the integration.
-The "yield" from gosia is in mb(mg/cm^2)/sr, where sr represents the solid
+After an integration, the cross section in mb is obtained by multiplying the yield by
-angle of the Ge.  In the case of a raw detector, it should be the total solid
+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
-angle of all crystals in the raw cluster.  So, after an OP,INTG or OP,INTI
+p-gamma counts expected using the equation following equation 6.44b in the manual:
-calculation, the cross section in mb is obtained by multiplying the yield by
-the Ge solid angle in sr and dividing by the target thickness in mg/cm^2.  You can also check the absolute
-p-gamma counts expected using equation after 6.44b in the most recent manual version:
-Detected p-gamma coincident events Ni = 10^(-30)[Q/qe][N_A/A] Y(I-->I_f) epsilon_p epsilon_gamma
+Detected p-gamma coincident events <math>N_i = 10^(-30) [Q / qe] [N_A / A] Y(I_i-->I_f) \epsilon_p \epsilon_\gamma \Delta \Omega_\gamma</math>
-DeltaOmega_gamma
-If your absolute efficiency is known well, then you should be able to retrieve
+If the absolute efficiency is known well, then it is possible to retrieve
-the actual counts in the peak, since you are putting the efficiency into the
+the actual counts measured in the photopeak by putting the efficiency into this
 equation.
-In the equation above and your equation (1), the epsilon_gamma is the absolute
+In the equation above the <math>epsilon_gamma</math> is the absolute
 efficiency as a fraction between 0 and 1 (not including angular effects already
-integrated in the "yield").  I think this is properly called the intrinsic
+integrated in the "yield").  Let this be called the absolute photopeak efficiency.
-efficiency, but I always worry that people understand the terms differently.  I
+The <math>\Delta\Omega_gamma</math> term is the solid angle of the Ge detector.  A typical absolute photopeak efficiency <math>\epsilon_\gamma<\math> is 10--15%.  If the solid angle subtended by the crystal is  ~0.1 sr, then for one crystal <math>\epsilon_\gamma \Delta\Omega_\gamma ~ 0.01<\math>.
-would call it the absolute photopeak efficiency, not efficiency per unit solid
-angle, because the solid angle is in the yield term and Delta_Omega.  The
-DeltaOmega_gamma is the solid angle of the crystal or cluster.  I would expect
-your efficiency epsilon_gamma to be 10--15%.  If you have about 0.1 sr solid
-angle subtended by a crystal, then for one crystal epsilon_gamma *
-DeltaOmega_gamma ~ 0.01, and for a cluster of 4 ~0.04.
-So you can see if the numbers match what you fit in the energy spectrum.
-The answer to your first question, is the factor N_gamma_p only the sum below
+If the laboratory setup and the EM matrix are accurately represented in the Gosia input, then the absolute counts can be obtained:
-the photo-peak, is yes, as long as you are using the photopeak efficiency as I
-mentioned above.
-You definitely don't need any other corrections for the cascade in Gosia's
+<pre>
-"yield."
+N
+<\pre>
-About the "singles," they are the latter: the total number of particles hitting
+Refer to the page on the [particle_singles], which is a cross section given in the same output with the integrated yields.
-the detector.  Gosia should reproduce this number using the "integrated
-rutherford cross section," which probably shouldn't be called "Rutherford,"
-because it includes all the inelastic events.  For the scattering kinematics,
-Gosia assumes that the Q-value is the energy of the first excited state--state
-#2 in LEVE.  You can change this using the CONT option NCM, if you think that
-the probability of that state is <<1, for example.  In that case, you might
-pick the ground state.  If you put
-OP,STAR
-OP,EXIT
-in place of OP,YIEL, you can quickly see the probabilities of all states in the
-excitation.
 Maybe the answer to your last question is obvious now, but...  I would not try