Difference between revisions of "Documents"

From Cuawiki
Jump to navigation Jump to search
 
(63 intermediate revisions by 6 users not shown)
Line 1: Line 1:
==[[PAC40]]==
+
== Publications ==
  
== Physics ==
+
* Ho-San Ko, [https://tel.archives-ouvertes.fr/tel-02927155 Neutral Pion Electroproduction and development of a Neutral Particle Spectrometer], tel-02927155, 2020UPASS129 (2020)
  
=== DVCS ===
+
* T. Horn, V.V. Berdnikov, et al., [https://arxiv.org/pdf/1911.11577.pdf Scintillating crystals for the Neutral Particle Spectrometer in Hall C at JLab], Nucl. Inst. Meth. A, Volume 956, 11 March 2020, 163375
[https://userweb.jlab.org/~rafopar/HallC/ Rafael's second report on DVCS simulations (including results for all energies from kinematics table)]
 
  
[http://www.vsl.cua.edu/cua_phy/images/a/af/Meeting_Report1.pdf Rafael's first report on DVCS simulations]
+
* T. Horn, [https://inspirehep.net/files/7beb57a5e4d83e6b1230427828b75cf2 A PbWO4-based Neutral Particle Spectrometer in Hall C at 12 GeV JLab], J.Phys.Conf.Ser. 587 (2015) 1, 012048 (CALOR2014 Proceedings)
  
[http://www.jlab.org/Hall-C/talks/01_24_13/hyde.pdf Charles presentation from Hall C meeting, 24 January 2013]
+
* [https://wiki.jlab.org/cuawiki/images/c/cc/Submission_pdf_proof_narrative.pdf SCINT2015 Proceedings]
  
[http://www.vsl.cua.edu/cua_phy/images/a/a7/Kinmat_search_results_HMS_angle_lt_13deg.pdf Study of effects on kinematics if require HMS angle to be >=13 deg (.pdf)]
+
== PAC Presentations and NPS Physics Notes ==
  
[http://www.vsl.cua.edu/cua_phy/images/4/4f/DVCS_meson_beam_time_comparison_summary.pdf Beam Time Sharing DVCS and pi0 (.pdf)]
+
===[[PAC46]]: TCS ===
  
=== WACS ===
+
===[[PAC45]]: WACS polarization observables ===
  
[https://wiki.jlab.org/cuawiki/index.php/File:RCS12_NewKinematics1.pdf New kinematics from David based on 8 Nov. 2013 collaboration meeting discussions (Nov 2013)
+
===[[PAC43]]: WACS polarization observables, TCS LOI ===
  
[http://www.vsl.cua.edu/cua_phy/images/6/60/Wacs_writeup1.pdf  Simon's report on WACS simulations]
+
===[[PAC42]]: WACS, pi0 photoproduction ===
  
[http://www.vsl.cua.edu/cua_phy/images/7/79/RCS-th.pdf Notes from Peter Kroll, Nov 2012]
+
===[[PAC40]]: DVCS/pi0 cross sections, SIDIS pi0, WACS ===
  
=== SIDIS mesons ===
 
  
see PAC40 proposal
 
  
=== DES mesons ===
+
=== Physics Notes ===
  
[http://www.vsl.cua.edu/cua_phy/images/9/94/Pi0-th.pdf Notes from Peter Kroll, Nov 2012]
+
'''DVCS/pi0 Cross Sections and SIDIS pi0'''
  
=== Neutral Pion Photoproduction ===
+
* [https://userweb.jlab.org/~rafopar/HallC/ Rafael's second report on DVCS simulations (including results for all energies from kinematics table)]
  
[https://wiki.jlab.org/cuawiki/index.php/File:Pi090_ratio.eps Ratio pi0/pi+ from Peter Kroll model at 90CM]
+
* [http://www.vsl.cua.edu/cua_phy/images/a/af/Meeting_Report1.pdf Rafael's first report on DVCS simulations]
  
[https://wiki.jlab.org/cuawiki/index.php/File:Pi0pip_tdep.eps Ratio pi0/pi+ t dependence from Peter Kroll model]
+
* [http://www.jlab.org/Hall-C/talks/01_24_13/hyde.pdf Charles presentation from Hall C meeting, 24 January 2013]
  
 +
* [http://www.vsl.cua.edu/cua_phy/images/a/a7/Kinmat_search_results_HMS_angle_lt_13deg.pdf Study of effects on kinematics if require HMS angle to be >=13 deg (.pdf)]
  
== Detector ==
+
* [http://www.vsl.cua.edu/cua_phy/images/4/4f/DVCS_meson_beam_time_comparison_summary.pdf Beam Time Sharing DVCS and pi0 (.pdf)]
  
* ''PMT specs'': Hamamatsu R4125, 19mm diameter, gain is about 8.7E+5 at 1.5kV max. anode voltage and rise time 2.5ns. This PMT was also used in Primex and we have designed a new active voltage divider that improves the performance of the PMT by a factor of 25. See the [https://wiki.jlab.org/cuawiki/images/a/ac/NSS2012_JLAB.pdf report at the 2012 IEEE NSS/MIC/RTSD conference] by V. Popov and H. Mkrtchyan.
+
* [http://www.vsl.cua.edu/cua_phy/images/9/94/Pi0-th.pdf Notes on exclusive pions from Peter Kroll, Nov 2012]
  
 +
'''Wide-Angle Compton Scattering (WACS)'''
  
* ''PbWO4 references'':
+
* [https://wiki.jlab.org/cuawiki/images/2/27/RCS12_NewKinematics1.pdf New kinematics from David based on 8 Nov. 2013 collaboration meeting discussions (Nov 2013)]
::* P. Adzic et al., "Radiation Hardness qualification of PbWO4 scintillation crystals for the CMS Electromagnetic Calorimeter", CMS Note 2009/016
 
::* A.A. Annenkov et al., "Lead Tungstate scintillation material", NIM A 490 (2002) 30-50
 
::* P. Yang et al., "Growth of large-size crystal of PbWO4 by vertical Brigdman method with multi-crucibles
 
::* R. W. Novotny, "The Electromagnetic Calorimetry of the PANDA Detector at FAIR", J. Phys. Conf. Serv. 404 012063 (2012)
 
  
 +
* [http://www.vsl.cua.edu/cua_phy/images/6/60/Wacs_writeup1.pdf  Simon's report on WACS simulations]
  
[http://www.vsl.cua.edu/cua_phy/images/a/a1/NPS-dose-rates.pdf Dose rate estimations for PbWO4 detector at 4m from target, at 1uA, and for a 10-cm long target]
+
* [http://www.vsl.cua.edu/cua_phy/images/7/79/RCS-th.pdf Notes from Peter Kroll, Nov 2012]
  
 +
'''WACS Neutral Pion Photoproduction'''
  
''Scattering Chamber Information:''
+
* [https://wiki.jlab.org/cuawiki/images/7/77/Pi090_ratio.eps Ratio pi0/pi+ from Peter Kroll model at 90CM]
  
::* outer diameter = 45 inches
+
* [https://wiki.jlab.org/cuawiki/images/9/93/Pi0pip_tdep.eps Ratio pi0/pi+ t dependence from Peter Kroll model]
  
::* inner diameter = 43.125 inches
+
= [[Magnet]] =
  
::* distance beam line to SHMS window = 1.25 inches
+
= Calorimeter =
  
So for a point target, the minimum angle is 58 mr or 3.4 degrees. For an extended target you will need to adjust, it becomes about 4 degree for a 15 cm target. So assume 3.5 degrees as rough number.
+
=== NPS Geant4 simulation for Hall C DVCS ===
  
 +
* [https://github.com/gboon18/HallC_NPS GitHub]: use DVCS_evt_gen/.
  
[http://www.vsl.cua.edu/cua_phy/images/9/97/Pi0_background-beam-pipe.pdf Study of possibilities for larger beam pipe assemblies]
+
* [https://wiki.jlab.org/cuawiki/images/f/fa/User_Guide.pdf A very short User Guide].
  
[http://www.vsl.cua.edu/cua_phy/images/9/99/Pi0_background-spectrum2.pdf Energy spectra for electrons, photons, positrons including fits]
+
* Information for 2023 update to Ho San KO GEANT4 model: [[Media:NPS_GEANT.pdf | NPS_GEANT.pdf]]
  
 +
==== NPS Beamline Technical Drawings ====
 +
* [[Media:67508-00026_S1_R-_BEAMLINE_NPS_ASSY-1.pdf | Overview Drawing 67508-00026]]
 +
* [[Media:67173-56159_S1_R-A_HALL-C_NPS_EXPERIMENT_BEAMLINE_SPOOL_PIECE-A.pdf |Spool Piece-A]]
 +
* [[Media:67173-56160_S1_R-B_HALL-C_NPS_EXPERIMENT_BEAMLINE_SPOOL_PIECE-B.pdf |Spool Piece-B]]
 +
* [[Media:67110-56841_S1_R-_CORRECTOR_ASSY_NPS.pdf | Corrector Coil main drawing]]
  
Rates and rates per crystal vs. angle relative to beam for: 4 m from target, 6.6 GeV beam energy, 1uA beam current, and 10-cm LH2 target for:
+
=== NPS software and calibration ===
  
[http://www.vsl.cua.edu/cua_phy/images/a/ae/Bgr_sweep_e100_g10.pdf Photon threshold=10 MeV]
+
* [https://wiki.jlab.org/cuawiki/images/9/9c/Energy_Calibration_of_the_NPS_Calorimeter.pdf Energy Calibration of NPS Calorimeter, June 2020] == [jroche] There is a mistake in the evaluation of match between the vertical coverage of the HMS and of the calorimeter. This 2020 document will be updated shortly, but for now, it is better to read  [https://hallcweb.jlab.org/wiki/images/2/22/NPS_ElasticCalibrations.pdf this document.]
  
[http://www.vsl.cua.edu/cua_phy/images/a/ae/Bgr_sweep_e100_g3.pdf Photon threshold=3 MeV]
+
=== Crystal characterization ===
  
 +
* [http://www.vsl.cua.edu/cua_phy/index.php/MainPage:Nuclear:NPS:PWO:CrystalLOG Table of results of SICCAS crystals produced in 2014 and 2015] - measurements carried out at CUA
  
[http://www.vsl.cua.edu/cua_phy/images/c/cb/Hamlet.pdf Hamlet's report on crystal properties from Hall C meeting, 24 January 2013]
+
* Results of tests of subsets of the 10+5 SICCAS produced crystals (2014) at Giessen, BNL, and Caltech
 +
::* Results of crystals 2, 3, 6, 8, and 9 from Giessen:
 +
::::* [https://wiki.jlab.org/cuawiki/images/9/9a/SICCAS_2015May_5old_dk.pdf Absorption coefficient]
 +
::::* [https://wiki.jlab.org/cuawiki/images/8/83/SICCAS_2015May_5old_T.pdf Transmittance]
 +
::::* Light Yields: [https://wiki.jlab.org/cuawiki/images/0/0a/SICCAS_2015May_5old_LY_2.pdf LY_2], [https://wiki.jlab.org/cuawiki/images/f/f3/SICCAS_2015May_5old_LY_3.pdf LY_3], [https://wiki.jlab.org/cuawiki/images/6/67/SICCAS_2015May_5old_LY_2_6.pdf LY_6], [https://wiki.jlab.org/cuawiki/images/a/a4/SICCAS_2015May_5old_LY_8.pdf LY_8], [https://wiki.jlab.org/cuawiki/images/3/37/SICCAS_2015May_5old_LY_9.pdf LY_9]
 +
::* [https://wiki.jlab.org/cuawiki/images/f/fe/4EIC_150608_SIC_PWO.pdf Results for crystals 5 and 11 from Caltech and comparison to CMS crystal performance]
 +
::* [https://wiki.jlab.org/cuawiki/images/2/2e/PWO_SIC_BNL_measurements.pdf Results for crystals 7 and 15 from BNL]
  
[http://www.vsl.cua.edu/cua_phy/images/a/ac/NSS2012_JLAB.pdf New Active PMT Base for PbWO4 (Popov, H. Mkrtchyan, presentation at IEEE, Nov 2012)]
+
* [http://www.vsl.cua.edu/cua_phy/images/c/cb/Hamlet.pdf Hamlet's report on crystal properties from Hall C meeting, 24 January 2013]
  
 +
* ''PbWO4 references'':
 +
::* P. Adzic et al., "Radiation Hardness qualification of PbWO4 scintillation crystals for the CMS Electromagnetic Calorimeter", CMS Note 2009/016
 +
::* A.A. Annenkov et al., "Lead Tungstate scintillation material", NIM A 490 (2002) 30-50
 +
::* P. Yang et al., "Growth of large-size crystal of PbWO4 by vertical Brigdman method with multi-crucibles
 +
::* R. W. Novotny, "The Electromagnetic Calorimetry of the PANDA Detector at FAIR", J. Phys. Conf. Serv. 404 012063 (2012)
  
Description of the PbWO4 detector option:
+
* [https://wiki.jlab.org/cuawiki/index.php/File:Crytur_dimensions.ods Table of CRYTUR crystals QA at JLab]
  
[https://indico.in2p3.fr/getFile.py/access?contribId=19&sessionId=3&resId=0&materialId=slides&confId=7052 Presentation at Orsay Workshop, Nov 2012]
+
=== PMTs ===
  
[http://www.jlab.org/exp_prog/proposals/12/C12-11-102.pdf PAC39 proposal, May 2012]
+
* ''PMT specs'': Hamamatsu R4125, 19mm diameter, gain is about 8.7E+5 at 1.5kV max. anode voltage and rise time 2.5ns. This PMT was also used in Primex and we have designed a new active voltage divider that improves the performance of the PMT by a factor of 25. See the [https://wiki.jlab.org/cuawiki/images/a/ac/NSS2012_JLAB.pdf report at the 2012 IEEE NSS/MIC/RTSD conference] by V. Popov and H. Mkrtchyan.
  
 +
* [http://www.vsl.cua.edu/cua_phy/images/a/ac/NSS2012_JLAB.pdf New Active PMT Base for PbWO4 (Popov, H. Mkrtchyan, presentation at IEEE, Nov 2012)]
  
 
'''Hamamatsu PMT Specs'''  11 Oct 2013, C.E.Hyde
 
'''Hamamatsu PMT Specs'''  11 Oct 2013, C.E.Hyde
Line 103: Line 119:
 
:: Cathode Lifetime data  [[Media:R4125_(100_uA_&_1000_h)_QG0016B.pdf]]
 
:: Cathode Lifetime data  [[Media:R4125_(100_uA_&_1000_h)_QG0016B.pdf]]
  
 +
=== NPS Dose Rate Estimates ===
  
== Magnet ==
+
* [http://www.vsl.cua.edu/cua_phy/images/a/a1/NPS-dose-rates.pdf Dose rate estimations for PbWO4 detector at 4m from target, at 1uA, and for a 10-cm long target]
  
  
== Light monitoring and Curing System ==
+
''Scattering Chamber Information:''
  
[https://wiki.jlab.org/cuawiki/index.php/File:NPS-Light-Monitoring-System.pdf Notes on Light Monitoring System from Hamlet]
+
::* outer diameter = 45 inches
  
[https://wiki.jlab.org/cuawiki/index.php/File:NPS-Curing-System.pdf Notes on Curing System from Hamlet]
+
::* inner diameter = 43.125 inches
  
 +
::* distance beam line to SHMS window = 1.25 inches
  
== Electronics ==
+
So for a point target, the minimum angle is 58 mr or 3.4 degrees. For an extended target you will need to adjust, it becomes about 4 degree for a 15 cm target. So assume 3.5 degrees as rough number.
 +
 
 +
 
 +
[http://www.vsl.cua.edu/cua_phy/images/9/97/Pi0_background-beam-pipe.pdf Study of possibilities for larger beam pipe assemblies]
 +
 
 +
[http://www.vsl.cua.edu/cua_phy/images/9/99/Pi0_background-spectrum2.pdf Energy spectra for electrons, photons, positrons including fits]
 +
 
 +
 
 +
Rates and rates per crystal vs. angle relative to beam for: 4 m from target, 6.6 GeV beam energy, 1uA beam current, and 10-cm LH2 target for:
 +
 
 +
[http://www.vsl.cua.edu/cua_phy/images/a/ae/Bgr_sweep_e100_g10.pdf Photon threshold=10 MeV]
 +
 
 +
[http://www.vsl.cua.edu/cua_phy/images/a/ae/Bgr_sweep_e100_g3.pdf Photon threshold=3 MeV]
 +
 
 +
 
 +
=== History of the NPS (2012) ===
 +
 
 +
* [https://indico.in2p3.fr/getFile.py/access?contribId=19&sessionId=3&resId=0&materialId=slides&confId=7052 Presentation at Orsay Workshop, Nov 2012]
 +
 
 +
* [http://www.jlab.org/exp_prog/proposals/12/C12-11-102.pdf PAC39 proposal, May 2012]
 +
 
 +
 
 +
= Light monitoring and Curing System =
 +
 
 +
[https://wiki.jlab.org/cuawiki/images/4/4d/NPS-Light-Monitoring-System.pdf Notes on Light Monitoring System from Hamlet]
 +
 
 +
[https://wiki.jlab.org/cuawiki/images/c/c4/NPS-Curing-System.pdf Notes on Curing System from Hamlet]
 +
 
 +
 
 +
= Electronics =
 +
 
 +
* [https://wiki.jlab.org/cuawiki/images/a/ac/Sawatzky-DAQ_update_01Feb2021.pdf Overview of Support and DAQ hardware and firmware, slow controls, and NPS integrated controls (from February 2021 Collaboration Meeting)]
  
 
* Experimental requirements on hardware:
 
* Experimental requirements on hardware:
Line 121: Line 170:
  
  
* [https://wiki.jlab.org/cuawiki/index.php/File:Fadc_time.pdf Note on fADC timing]
+
* [https://wiki.jlab.org/cuawiki/images/4/47/Fadc_time.pdf Note on fADC timing from C. Cuevas]
 +
 
 +
= [[High Intensity Photon Source]] =

Latest revision as of 07:19, 10 July 2023

Publications

PAC Presentations and NPS Physics Notes

PAC46: TCS

PAC45: WACS polarization observables

PAC43: WACS polarization observables, TCS LOI

PAC42: WACS, pi0 photoproduction

PAC40: DVCS/pi0 cross sections, SIDIS pi0, WACS

Physics Notes

DVCS/pi0 Cross Sections and SIDIS pi0

Wide-Angle Compton Scattering (WACS)

WACS Neutral Pion Photoproduction

Magnet

Calorimeter

NPS Geant4 simulation for Hall C DVCS

NPS Beamline Technical Drawings

NPS software and calibration

Crystal characterization

  • Results of tests of subsets of the 10+5 SICCAS produced crystals (2014) at Giessen, BNL, and Caltech
  • Results of crystals 2, 3, 6, 8, and 9 from Giessen:
  • PbWO4 references:
  • P. Adzic et al., "Radiation Hardness qualification of PbWO4 scintillation crystals for the CMS Electromagnetic Calorimeter", CMS Note 2009/016
  • A.A. Annenkov et al., "Lead Tungstate scintillation material", NIM A 490 (2002) 30-50
  • P. Yang et al., "Growth of large-size crystal of PbWO4 by vertical Brigdman method with multi-crucibles
  • R. W. Novotny, "The Electromagnetic Calorimetry of the PANDA Detector at FAIR", J. Phys. Conf. Serv. 404 012063 (2012)

PMTs

  • PMT specs: Hamamatsu R4125, 19mm diameter, gain is about 8.7E+5 at 1.5kV max. anode voltage and rise time 2.5ns. This PMT was also used in Primex and we have designed a new active voltage divider that improves the performance of the PMT by a factor of 25. See the report at the 2012 IEEE NSS/MIC/RTSD conference by V. Popov and H. Mkrtchyan.

Hamamatsu PMT Specs 11 Oct 2013, C.E.Hyde

  • specs on standard 1" PMTs:
R8619 10 stage PMT
R9800 8 stage PMT
Low profile (short) 29mm R7111 PMT Media:R7111.pdf
Magnetic Field Response Media:R7877_Magnetic_Field_Characteristics.pdf
Cathode Lifetime data Media:QG1369A_R7877_Life.pdf
Magnetic Field Response Media:R4125_Effects_of_Magnetic_Fields.pdf
Cathode Lifetime data Media:R4125_(100_uA_&_1000_h)_QG0016B.pdf

NPS Dose Rate Estimates


Scattering Chamber Information:

  • outer diameter = 45 inches
  • inner diameter = 43.125 inches
  • distance beam line to SHMS window = 1.25 inches

So for a point target, the minimum angle is 58 mr or 3.4 degrees. For an extended target you will need to adjust, it becomes about 4 degree for a 15 cm target. So assume 3.5 degrees as rough number.


Study of possibilities for larger beam pipe assemblies

Energy spectra for electrons, photons, positrons including fits


Rates and rates per crystal vs. angle relative to beam for: 4 m from target, 6.6 GeV beam energy, 1uA beam current, and 10-cm LH2 target for:

Photon threshold=10 MeV

Photon threshold=3 MeV


History of the NPS (2012)


Light monitoring and Curing System

Notes on Light Monitoring System from Hamlet

Notes on Curing System from Hamlet


Electronics

  • Experimental requirements on hardware:


High Intensity Photon Source