Difference between revisions of "PhD Proposal Tamar"
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In semi-inclusive scattering experiment, where the scattered electron and one or more hadrons in coincidence are detected, provides a powerful tool for an understanding the structure of nucleons. | In semi-inclusive scattering experiment, where the scattered electron and one or more hadrons in coincidence are detected, provides a powerful tool for an understanding the structure of nucleons. | ||
− | Models provide better understanding of the nucleon structure and "play an important role " in the explanation of the | + | Models provide better understanding of the nucleon structure and "play an important role " in the explanation of the experimental data. |
Measurement of the double spin asymmetry and the ratio of the polarized valence down quark distribution function to the unpolarized can be used to see the difference between the numerous descriptions of the nucleon structure. pQCD and a hyperfine pertubed constituent quark model predict the scaling variable x_b -> 1 corresponds to A_N~1. On the other hand, the well-studied SU(6) constituent quark model for x_b=1 state that A_p=5/9 and A_n=0. | Measurement of the double spin asymmetry and the ratio of the polarized valence down quark distribution function to the unpolarized can be used to see the difference between the numerous descriptions of the nucleon structure. pQCD and a hyperfine pertubed constituent quark model predict the scaling variable x_b -> 1 corresponds to A_N~1. On the other hand, the well-studied SU(6) constituent quark model for x_b=1 state that A_p=5/9 and A_n=0. | ||
− | The inclusive double spin asymmetry can be written in terms of valence quark | + | The inclusive double spin asymmetry can be written in terms of valence quark distribution functions: |
where deltaq_v and q_v are polarized and unpolarized quark distribution functions. Quark distribution function q(x) is the probability(density) of finding a quark with fraction x of the proton(neutron) momentum. | where deltaq_v and q_v are polarized and unpolarized quark distribution functions. Quark distribution function q(x) is the probability(density) of finding a quark with fraction x of the proton(neutron) momentum. |
Revision as of 20:25, 10 August 2009
Tamar PhD Proposal
Abstract
Introduction
Physics Motivation
Tamuna will have a rough draft of this by Friday July 31,2009.
In semi-inclusive scattering experiment, where the scattered electron and one or more hadrons in coincidence are detected, provides a powerful tool for an understanding the structure of nucleons.
Models provide better understanding of the nucleon structure and "play an important role " in the explanation of the experimental data.
Measurement of the double spin asymmetry and the ratio of the polarized valence down quark distribution function to the unpolarized can be used to see the difference between the numerous descriptions of the nucleon structure. pQCD and a hyperfine pertubed constituent quark model predict the scaling variable x_b -> 1 corresponds to A_N~1. On the other hand, the well-studied SU(6) constituent quark model for x_b=1 state that A_p=5/9 and A_n=0.
The inclusive double spin asymmetry can be written in terms of valence quark distribution functions:
where deltaq_v and q_v are polarized and unpolarized quark distribution functions. Quark distribution function q(x) is the probability(density) of finding a quark with fraction x of the proton(neutron) momentum.
Experimental Setup
Tamuna will finish this section by Friday July 31, 2009
Target
- Target Materials
The EG1 experiment at Jefferson Lab used five different targets during their polarized structure function measurement program. The target materials used during the EG1b experiment were frozen ammonia, Prok Thesis. Three other targets, C12, liquid He4 and frozen N15 were used to employ several methods for removing the Nitrogen contributions to the measured structure functions made using NH3 and ND3.
Ammonia targets were selected because of their ability to produce high polarization and they are less effected by beam radiation. On the other hand, the damage caused by this radiation can be repair by annealing(heating process). In addition, ammonia target has a high ratio of free nucleons (~3/18) approximately 16.5 % for and 26.6 % for . One disadvantage of choosing ammonia is the polarization background caused by 15N(spin - 1/2), or 14N(spin - 1), which was eliminated by measuring 15n polarization.[SChen_FSU_thesis]
- Magnet
The 5 T magnetic field produced by a superconducting pair of Helmholtz coils and parallel to the beam direction, provide the hyperfine splittings needed to polarize the target material using ? Ghz RF waves. The uniformity of the field is varying less than
- The Evaporation Refrigerator
The target is cooled to ~ 1 K using the helium, which is supplied from the 1 K
- The Target Inserts
The target insert was designed and built by the INFN of Genova. The target cells with a thickness of 0.2 mm were made out of polychlorotrifluoroethylene (PCTFE), it is a hydrogen-free material and would not produce an NMR background, also it is not effected by radiation as much as other materials. Each target cell is 15 mm in diameter and 10 mm in length sealed by a 0.025 mm thick aluminum foil at entrance window and 0.05 mm thick kapton foil at exit window. [ref 4]
The target insert has the four target cells. Two of them were filled with ammonia beads: the top one with and the other one with . was followed by carbon ( ) disk with a thickness of 2.3 mm and the fourth cell was left empty. The carbon and the empty cells were used to measure background.[ref 4]
The Nuclear Magnetic Resonance(NMR) coils were wrapped around the outside surface of the cells in order to reduce the background, maximize the amount of ammonia in the target cells and monitor the polarization of the target. The geometry of the NMR coils were chosen so that they would be maximally sensitive to the target polarization. They were made out of CuNi material with a thickness of 0.15 mm and bent into rectangular loops. The temperature sensors(thermocouples, RuO resistors) were attached to the target insert at different locations to monitor the temperature of the target materials.[ref 4]
A second target insert was designed and built by the Jefferson Lab Polarized Target Group to measure the background using solid
The target insert during the experiment is moved up or down using the stepping motor, which means that the target can be changed automatically.[ref 4]
The CEBAF Large Acceptance spectrometer
The CEBAF Large Acceptance spectrometer is a detector at Thomas Jefferson National Accelerator Facility which covers particle detection almost on 360 degree. The detector is divided into six sectors, each of them including a superconducting coil, which produce a toroidal magnetic field along the beam direction. As a charge particle tracking system was used a set of drift chambers divided by three regions, totally consisting of 18 drift chambers. After the drift chamber system the CLAS detector is equipted with Cherenkov counter for seperating electrons from the pions and with scintillators for determination of the Time of Flight of a charge particle. At the end of the detector the particle identification and timing(resolution) is achieved using electromagnetic calorimeters.
- The Torus Magnet
The torus magnet for CLAS detector consists the six superconducting coils located around the beam line in a toroidal geometry, producing the magnetic field in the
The maximum current for the CLAS magnet is 2860 A, in the forward direction the total magnetic field is 2.5 T-m and at a polar scattering angle with 90 degrees 0.6 T. The magnet itself is around 5 m in diameter and 5 m in length. The coils of the magnet are cooled by liquid helium circulating through cooling tubes to a superconducting temperature of 4.5 K.[[Yelena Alexsandrovna Pork, Measurement of The spin Structure Functions of The Proton in The resonance Region.]]
One can find out the charged particles momentum knowing the trajectory of a particle. In Eg1b experiment, the operated torus values were: 2250, -2250, 1500, -1500.
- Drift Chambers
In order to track the charged particles in the EG1b experiment a drift chamber system is used. A drift chamber is a particle tracking detector that measures the drift time of ionization electrons in a gas to calculate the spacial position of an ionizing particle.
The electric field in a drift chamber is produced by the anode(sense wire) and cathode(field wire) wires. The charge particle traveling trough the drift chamber ionizes the gas, producing the electrons that drift to the anodes. After time(drift time) electrons are collected at the anode(sense wire) generating the pulse at t time. The distance from the traversing particle to the sense wire can be calculated using the drift time and velocity.
The drift chamber system in CLAS detector is divided into three regions, each consisting six separate chambers(six sectors). Region 1 (R1) chambers are placed closest to the target, where the magnetic filed is low. Region 2 (R2) chambers are in a high magnetic field region, they are located between the magnetic coils. Region 3 (R3) chambers are outside the torus coils and they are largest ones. The drift chambers contain three type of wires stretched between the endplates: sense, guard and field. The endplates are attached to the drift chamber so that the angle the form is equal to 60 degrees. Each drift chamber is subdivided into two separate superlayers. Each superlayer with six layers of drift cells, and each drift cell with one sense wire surrounded by six field wires forming a hexagonal shape([1]). Each superlayer is surrounded by guard wires at a positive potential to stimulate the electric field caused by the drift cells. The sense wire is operated at positive potential and the field wire at negative. In each superlayer the distance between the sense and field wire increases with the radial distance from the target. In R1 the average distance between the sense and field is 0.7 cm, in R2 1.15 cm and in R3 2.0 cm.
The gas used to fill the CLAS drift chamber is a 90 - 10 % mixture of the argon(Ar) and , where Ar has an ionization gain of . Inside the drift chamber the constant pressure is provided by outflowing the gas. The chamber endplates are equipped with the circuit board with a single channel differential pre-amplifier for each sense wire.
- Cherenkov detector
The threshold CLAS Cherenkov detector is used to distinguish electrons from pions. The mixture gas used to fill the Cherenkov counter is perfluorobutane
The Cherenkov detector was designed to maximize the coverage in each of the sectors up to an angle degrees.
As a light collector were used the system of mirrors , the light collecting cones and photomultiplier tubes(PMTs). In the extreme regions of the angular acceptance of the spectrometer the number of detected photoelectrons is too low. To get acceptable efficiency of the detector in these regions photomultiplier tubes were placed. The calibration of the Cherenkov detector is in terms of the collected number of photoelectrons.
- Scintillators
The CEBAF Large Acceptance Spectrometer (CLAS) is equipped with 288 scintillator counters. The purpose of the scintillator is to determine the time of flight for the charged particles and to trigger it in coincidence with another detector system for the particle identification. The time of flight system is built so that time resolution at small polar angles
The time of flight system is located between the Cherenkov detectors and electromagnetic calorimeters. The scintillator strips(BC_408) are located perpendicularly to the average particle trajectory with an angular polar coverage of 1.5 degrees. Each sector of The CLAS detector consists of 48 scintillator strips with a thickness of 5.08 cm. The length of the scintillators varies from 30 cm to 450 cm and the width is between 15 cm at small polar angles and 22 cm for the large angles.
- Calorimeter
The CLAS detectur contains 8 modules of electromagnetic calorimeter. A calorimeter is a device that measures the total energy deposited by a crossing particle. They are useful in detecting neutral particles and distinguishing between electrons and hadrons due to their different mechanism of depositing energy. The CLAS calorimeter has three main functions:
1) detection of electrons at energies above 0.5 GeV;
2) detection of photons with energies higher than 0.2 GeV;
3) detection of neutrons, with discrimination between photon and neutrons using time-of-flight technique.
6 calorimeter modules of the CLAS detector are placed in each sector in the forward region (polar angle of 10-45 degrees, forward angle calorimeter), while the other two modules are located at large angles in sectors 1 and 2(50-70 degrees, large angle calorimeter). The forward calorimeter has a lead/scintillator thickness ratio 0.2, with 40 cm of scintillators and 8 cm of lead per module. The lead-scintillator sandwich is shaped as a equlaterial triangle in order to match the hexagonal geometry of the CLAS detector. It is made of 39 layers of a 10 mm BC_412 scintillator and lead sheet of thickness of 2.2 mm. Each scintillator layer contains 36 strips parallel to one side of the triangle, with this configuration each orientation is rotated by 120 degrees from another one. This gives three views each containing 13 layers providing stereo information of the location of the energy deposition.
To improve hadron identification, there was provided longitudinal sampling of the shower. Each set of 13 layers were subdivided into an inner 5 layers and outer 8 layers stack.