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| | <li> Angle restrictions with DVCS calorimeter in place: | | <li> Angle restrictions with DVCS calorimeter in place: |
| | <ol> | | <ol> |
| − | <li> HRS-BL: 26.5 to 45 degrees | + | <li> HRS-BL: 17.9 to 45 degrees |
| | <li> HRS-BR: 46.2 to 74.5 degrees | | <li> HRS-BR: 46.2 to 74.5 degrees |
| | </oL> | | </oL> |
| Line 31: |
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| | * Initial checks of beam position and raster. | | * Initial checks of beam position and raster. |
| | | | |
| − | === HRS Checkout (Experts) === | + | ===[[ HRS Checkout (Experts) ]]=== |
| − | The detector checkout is best done using a fairly uniform illumination, which is
| + | |
| − | provided for by 20 μA on the central Carbon target at the following kinematics:
| + | |
| | | | |
| − | E' = 3.056 GeV, θ = 19 degrees (W<sup>2</sup> = 2.53 GeV, Q<sup>2</sup> = 2.43 GeV<sup>2</sup>). The
| + | ===[[ Beamline ]]=== |
| − | HRS electron rates should be about 270 Hz.
| + | |
| − | <table border="1" style="width:80%">
| + | |
| − | <tr>
| + | |
| − | <td>E<SUB>beam</SUB> [GeV]</td>
| + | |
| − | <td>P<sub>0</sub> [GeV/c]</td>
| + | |
| − | <td>θ<SUB>e</SUB> [deg]</td>
| + | |
| − | <td>Collimator</td>
| + | |
| − | <td>Target</td>
| + | |
| − | <td>Fast Raster <br> X x Y </td>
| + | |
| − | <td>Beam Current</td>
| + | |
| − | <td>Trigger</td>
| + | |
| − | </tr>
| + | |
| − | <tr>
| + | |
| − | <td>7.3</td>
| + | |
| − | <td>3056</td>
| + | |
| − | <td>19.0</td>
| + | |
| − | <td>None</td>
| + | |
| − | <td>Single Carbon</td>
| + | |
| − | <td>off</td>
| + | |
| − | <td>20μA</td>
| + | |
| − | <td>S0&&S2m</td>
| + | |
| − | </tr>
| + | |
| − | </table>
| + | |
| − | <ol>
| + | |
| − | <li> With the above kinematics, take a run (at least 100K events or 10 minutes) and verify that all detector channels are working.
| + | |
| − | <li> Using the same run, produce a ROOT tree, and do the following: make a spectrum of x vs. y at the focal plane. What you should see is a "spider" with 5 legs. The non-straightness of the central legs indicates there is an offset in the Z or Y direction. If you don't see a "spider" or something resembling it, then of of the polarities of the HRS magnets is set wrong (or a magnet is off).
| + | |
| − | <li> Check that the signals are well timed.
| + | |
| − | <li> Determine correct thresholds.
| + | |
| − | <li> Verify all scalers are incrementing.
| + | |
| − | <li> Check for double pulsing and time the wire chamber signals.
| + | |
| − | <li> Are the scintillator signals for on scale in the scintillator ADCs?
| + | |
| − | <li> PID threshold checks.
| + | |
| − | </ol>
| + | |
| | | | |
| − | === Beamline === | + | ===[[ Beamline (2014) ]]=== |
| | | | |
| − | ==== Initial BPM/Raster checks/Beam centering ==== | + | ===[[ HRS Detector Calibrations ]]=== |
| − | <ol>
| + | |
| − | <li> First MCC centers the beam on the beam dump using the ion chambers.
| + | |
| − | <li> Ideally the beam should be able to pass cleanly through the Compton chicane. But this is not a requirement.
| + | |
| − | <li>Check the raster size using the spot++ tool. After the target boiling studies result, the final raster size for production data will be decided.<br>
| + | |
| − | <li>Insert carbon hole target to center the beam position with respect to the hole. Setup the raster to 2*2 mm, use spot++ to check if the beam is centered around the hole. Move the beam if necessary.
| + | |
| − | </ol>
| + | |
| | | | |
| − | ==== Superharp Scan with Raster off/on ==== | + | ===[[ Beam Position on Target ]]=== |
| − | <ol>
| + | |
| − | <li> Scan the two superharps near the target with raster off. Obtain two pictures including the three wires for each harp.
| + | |
| − | <li> Make sure the three wires are clearly visible and have reasonable resolution: ~ 100-200 μm.
| + | |
| − | <li> Repeat with raster on. In this case, you may not see the wires clearly.
| + | |
| − | <li> Make sure to post the results in the Hall A electronic logbook or Halog.
| + | |
| − | </ol>
| + | |
| | | | |
| − | ==== BPM Calibrations (Bullseye Scan) ==== | + | ===[[ Spectrometer Optics ]]=== |
| − | <FONT Color="Green">How to perform a bulls eye scan</FONT>:
| + | |
| | | | |
| − | 1. You need unrastered beam:
| + | ===[[ Spectrometer Optics 2014 ]]=== |
| − | - <FONT Color="red">caution you should not do this with a target requiring rastered beam</FONT>
| + | |
| − | - use carbon, BeO, optics, or in the worst case empty instead
| + | |
| | | | |
| − | 2. Ask MCC to steer the beam to the nominal center of the target.
| + | === [[ Luminosity Scans - Low Rate (Target Boiling) ]]=== |
| | | | |
| − | 3. Wait until beam is stable and have MCC perform a harp scan for the two superharps near the target (1H03A and 1H03B) and take a coda run during the
| + | === [[ Initial HRS Elastic Checks ]]=== |
| − | same time. Start the coda run first before asking MCC. Request MCC to make an ELOG entry with the results, you should see all three harp wires.
| + | |
| − | Record ELOG entry numbers.
| + | |
| − | | + | |
| − | 4. Ask MCC then to steer the beam to positions around the nominal center:
| + | |
| − | - cover at least the area the raster will cover: (2,2), (2,-2), (-2,-2), (-2,2) and repeat (0,0)
| + | |
| − | - repeat harp and coda runs for each position
| + | |
| − | | + | |
| − | 5. Record Harp scan run numbers and corresponding CODA run number for each beam position.
| + | |
| − | | + | |
| − | 6. Make a record of the harp scans and CODA runs in the HAlog.
| + | |
| − | | + | |
| − | <FONT Color="Green">How to analyze the bulls eye scan</FONT>:
| + | |
| − | - detailed instructions can be found at the [http://hallaweb.jlab.org/root/doc/bpm.html Analyzing BPMs] website.
| + | |
| − | - <FONT Color="red">the shift crew is not expected to analysis the bulls eye scan</FONT>.
| + | |
| − | | + | |
| − | ==== BCM Calibrations [2 hours] ==== | + | |
| − | <ol>
| + | |
| − | <li> Warn MCC a few hours beforehand.
| + | |
| − | <li> The Hall A BCM and scalers need to be cross-calibrated to the Faraday cup and a BCM in the accelerator (OLO2) and the Hall A Unser.
| + | |
| − | <li> Before beginning the procedure, make sure the Hall A BCM logger is started, which will record the signals from all relevant BCM used during the calibration.
| + | |
| − | <li> Also start a HRS run to record the scalers during the calibration procedure.
| + | |
| − | <li> It is useful to have someone over in MCC to help coordinate the calibration with them.
| + | |
| − | <li> Take data on carbon target with I = 10, 20, 30, 40 50, 60, 70, 80, 90, 100 μA (or as high a current as available).
| + | |
| − | </ol>
| + | |
| − | | + | |
| − | ==== ARC Energy Measurement [? hours] ====
| + | |
| − | <ol>
| + | |
| − | <li> The procedure will be conducted by Doug Higinbotham in coordination with MCC.
| + | |
| − | <li> Notify Doug and MCC a few hours beforehand to make sure they are ready and available.
| + | |
| − | </ol>
| + | |
| − | | + | |
| − | === Spectrometer Optics ===
| + | |
| − | * Time estimate: 1-2 hours
| + | |
| − | ==== Procedure with Sieve-slit ====
| + | |
| − | * A Hall A Tech may be required to install the 2-inch lead sieve-slit collimator onto the front face of the HRS.
| + | |
| − | * Take a sieve slit run with the multi-foil carbon target for the inelastic kinematics in the table.
| + | |
| − | * If you need to increase the spectrometer momentum setting, make sure you cycle Q2 and Q3 as per the cycling procedure.
| + | |
| − | * Repeat the above with the beam position shifted so that you see a vertical shift by one row.
| + | |
| − | * Rates assume 5 carbon foils, only 9 out of 25 sieve holes have events (~ 0.146 mSr acceptance), and 9% delta acceptance.
| + | |
| − | | + | |
| − | <table border="1" style="width:80%">
| + | |
| − | <tr>
| + | |
| − | <td>E<SUB>beam</SUB> [GeV]</td>
| + | |
| − | <td>P<sub>0</sub> [GeV/c]</td>
| + | |
| − | <td>θ<SUB>e</SUB> [deg]</td>
| + | |
| − | <td>Q<SUP>2</SUP> [GeV<SUP>2</SUP>]</td>
| + | |
| − | <td>W [GeV]</td>
| + | |
| − | <td> Rate [Hz] at 20 μA</td>
| + | |
| − | <td> minutes for 100k events at 20 μA</td>
| + | |
| − | </tr>
| + | |
| − | <tr>
| + | |
| − | <td>7.3</td>
| + | |
| − | <td>3200</td>
| + | |
| − | <td>19.0</td>
| + | |
| − | <td>2.5</td>
| + | |
| − | <td>2455</td>
| + | |
| − | <td>15</td>
| + | |
| − | <td>110</td>
| + | |
| − | </tr>
| + | |
| − | <tr>
| + | |
| − | <td>7.3</td>
| + | |
| − | <td>2019</td>
| + | |
| − | <td>19.0</td>
| + | |
| − | <td>1.6</td>
| + | |
| − | <td>3030</td>
| + | |
| − | <td>24</td>
| + | |
| − | <td>70</td>
| + | |
| − | </tr>
| + | |
| − | </table>
| + | |
| − | | + | |
| − | <b>Alternative rates with 1-inch tungsten sieve slit: </b>
| + | |
| − | * Assumes that 49 out of the 63 holes are seen (~ 0.52 mSr acceptance); however, the acceptance is reduced by 85%, <br> since not all foils will see all holes.
| + | |
| − | * Rates assume 5 carbon foils and 9% delta acceptance.
| + | |
| − | <table border="1" style="width:80%">
| + | |
| − | <tr>
| + | |
| − | <td>E<SUB>beam</SUB> [GeV]</td>
| + | |
| − | <td>P<sub>0</sub> [GeV/c]</td>
| + | |
| − | <td>θ<SUB>e</SUB> [deg]</td>
| + | |
| − | <td>Q<SUP>2</SUP> [GeV<SUP>2</SUP>]</td>
| + | |
| − | <td>W [GeV]</td>
| + | |
| − | <td> Rate [Hz] at 20 μA</td>
| + | |
| − | <td> minutes for 200k events at 20 μA</td>
| + | |
| − | </tr>
| + | |
| − | <tr>
| + | |
| − | <td>7.3</td>
| + | |
| − | <td>3056</td>
| + | |
| − | <td>19.0</td>
| + | |
| − | <td>2.4</td>
| + | |
| − | <td>2533</td>
| + | |
| − | <td>58</td>
| + | |
| − | <td>58</td>
| + | |
| − | </tr>
| + | |
| − | </table>
| + | |
| − | | + | |
| − | ==== Procedure without Sieve-slit ====
| + | |
| − | * Next take a run at the following kinematics without the sieve-slit collimator.
| + | |
| − | * If you need to increase the spectrometer momentum setting, make sure you cycle Q2 and Q3 as per the cycling procedure.
| + | |
| − | * Rates assume 5 carbon foils, 6 mSr acceptance, and 9% delta acceptance.
| + | |
| − | <table border="1" style="width:80%">
| + | |
| − | <tr>
| + | |
| − | <td>E<SUB>beam</SUB> [GeV]</td>
| + | |
| − | <td>P<sub>0</sub> [GeV/c]</td>
| + | |
| − | <td>θ<SUB>e</SUB> [deg]</td>
| + | |
| − | <td>Q<SUP>2</SUP> [GeV<SUP>2</SUP>]</td>
| + | |
| − | <td>W [GeV]</td>
| + | |
| − | <td> Rate [Hz] at 20 μA</td>
| + | |
| − | <td> minutes for 400k events at 20 μA</td>
| + | |
| − | </tr>
| + | |
| − | <tr>
| + | |
| − | <td>7.3</td>
| + | |
| − | <td>3.200</td>
| + | |
| − | <td>19.0</td>
| + | |
| − | <td>2.5</td>
| + | |
| − | <td>2455</td>
| + | |
| − | <td>623</td>
| + | |
| − | <td>11</td>
| + | |
| − | </tr>
| + | |
| − | <tr>
| + | |
| − | <td>7.3</td>
| + | |
| − | <td>2.019</td>
| + | |
| − | <td>19.0</td>
| + | |
| − | <td>1.6</td>
| + | |
| − | <td>3030</td>
| + | |
| − | <td>975</td>
| + | |
| − | <td>7</td>
| + | |
| − | </tr>
| + | |
| − | </table>
| + | |
| − | | + | |
| − | ==== Elastic from Hydrogen ====
| + | |
| − | | + | |
| − | Elastic electron-proton measurement. Assuming a 15 cm LH2 target, a spectrometer acceptance of 6 msr and elastic from Eric's rate program to compute the cross-section. Taking data at 7.3 GeV with the given momentum restrictions is time consuming.<br> (Table borrowed from DVCS3 wiki page)<br>
| + | |
| − | <table border="1" style="width:80%">
| + | |
| − | <tr>
| + | |
| − | <td>E<SUB>beam</SUB> (GeV)</td>
| + | |
| − | <td>k' (GeV)</td>
| + | |
| − | <td>θ<SUB>e</SUB> (deg)</td>
| + | |
| − | <td>Q<SUP>2</SUP> (GeV<SUP>2</SUP>)</td>
| + | |
| − | <td> Rate [Hz] at 20 μA</td>
| + | |
| − | <td> minutes for 5.4k events at 20& mu;A</td>
| + | |
| − | </tr>
| + | |
| − | <tr>
| + | |
| − | <td>7.3</td>
| + | |
| − | <td>3.2</td>
| + | |
| − | <td>33.4</td>
| + | |
| − | <td>7.7</td>
| + | |
| − | <td>1.5</td>
| + | |
| − | <td>60</td>
| + | |
| − | </tr>
| + | |
| − | <tr>
| + | |
| − | <td>5.5</td>
| + | |
| − | <td>3.2</td>
| + | |
| − | <td>28.7</td>
| + | |
| − | <td>4.3</td>
| + | |
| − | <td>15</td>
| + | |
| − | <td> 6</td>
| + | |
| − | </tr>
| + | |
| − | </table>
| + | |
| − | | + | |
| − | === [[ Luminosity Scans - Low Rate (Target Boiling) ]]===
| + | |
The following items should be performed during the first 1-1.5 shifts with beam on target:
