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Premium member Presentation Transcript Slide1: MuCap High-Precision Measurement of Muon Capture on the Proton University of California, Berkeley (UCB and LBNL) Petersburg Nuclear Physics Institute Paul Scherrer Institut University of Illinois, Urbana-Champaign Universite Catholique de Louvain TU Munich University of Kentucky Boston University Tom Banks APS DNP Fall Meeting 1 November 2003Experimental Goal: Experimental Goal Our goal is to measure the rate Λs of muon capture on the proton to 1% precision. This is a semileptonic weak interaction process, and (in our experiment) capture occurs predominantly from the hyperfine singlet atomic bound state. A 1% measurement of Λs determines gp – the “weak nucleonic charged current induced pseudoscalar form factor” – to < 7% precision. gp is the least well-known of the weak nucleonic c.c. form factors, and there is significant disagreement among previous gp measurements, and theory.Experimental Technique: Experimental Technique “Lifetime” or “Disappearance” Method For μ– in hydrogen, muon capture competes with muon decay: This rate competition decreases the observed μ– lifetime from the vacuum lifetime, which we measure separately with μ+ :Experimental Technique: Experimental Technique “Lifetime” or “Disappearance” Method Since our experiment can only observe the decay products e+ and e–, muon capture produces a small downward deflection of the μ– lifetime curve from the μ+ “vacuum” lifetime curve : The capture rate is easily calculated from the measured lifetimes: counts time μ+ μ – How Is This Experiment Superior?: How Is This Experiment Superior? High Statistics: In order to measure ΛS to 1% precision, we intend to measure both μ+ and μ– lifetimes to the level of 10 ppm, which requires recording 1010 decay events for each species. This is possible through our unique combination of detectors and analysis capabilities. Improved Target: We use 10 bar, ultra-pure protium gas (impurities at 10–8 level, deuterium-depleted H2 to 1 ppm). This eliminates molecular formation complications, and dramatically reduces distortions in the lifetime histograms. Experimental Setup – Apparatus: Experimental Setup – Apparatus entrance scintillator (t = 0) muPC1 muPC2 TPC ePC2 ePC1 eSC (Hodoscope) μ beam Muon Detectors Electron Detectors2003 Experimental Run: 2003 Experimental Run The MuCap experiment is conducted at the Paul Scherrer Institut (PSI) near Zürich, CH. We spent March → August 2003 assembling experiment; recorded data from September → mid-October.2003 Experimental Run: In spite of its technical complexity, MuCap is running and has achieved some excellent first physics results: 2003 Experimental Run First combined assembly of muon detectors (including functional TPC), electron detectors, and high-speed DAQ. We performed extensive systematic checks on the detectors. 2003 Experimental Run: 2003 Experimental Run We achieved gas impurity levels of 10–7, as determined from software analysis... ... impurity capture events are visible in the TPC data. We also performed an intentional nitrogen-doped run (few ppm), for precision calibration.2003 Experimental Run: 2003 Experimental Run From September 25 → October 8 we estimate to have recorded ~ 109 good μ– TPC stops. We will spend the coming year analyzing this data and extract a 10% measurement of Λs.Slide11: lOP (ms-1) cP-Theory RMC mCap proposed exp theory update from Gorringe & Fearing gp OMC Saclay In situ gas cleaning and quality monitoring TPC should reach full voltage and see decay electrons ePC2 will be completed, allowing for electron track vectorization 1010 muon stops Outlook 2004 2003 Experimental Run – Limitations: 2003 Experimental Run – Limitations Poor muon stopping fraction: We expected to stop ~ 80% of all incident muons in the TPC. Instead, we observed (at best) good muon stops only 32% of the time. The reasons for this discrepancy are still being explored. Muon beam stopping distribution inside TPC z Initial beam stop profile, with all muon detectors in place. Note the large low momentum scattering in the tail of the beam. Stopping fraction was ~ 20%. Final beam stop profile, following the removal of muPC1– the stopping fraction improved to 32%. Note the improved Gaussian shape. This has called into question the utility of muPC1,2. You do not have the permission to view this presentation. In order to view it, please contact the author of the presentation.
APS DNP 1November2003 Haggrid Download Post to : URL : Related Presentations : Share Add to Flag Embed Email Send to Blogs and Networks Add to Channel Uploaded from authorPOINTLite Insert YouTube videos in PowerPont slides with aS Desktop Copy embed code: (To copy code, click on the text box) Embed: URL: Thumbnail: WordPress Embed Customize Embed The presentation is successfully added In Your Favorites. Views: 23 Category: Entertainment License: All Rights Reserved Like it (0) Dislike it (0) Added: October 26, 2007 This Presentation is Public Favorites: 0 Presentation Description No description available. Comments Posting comment... Premium member Presentation Transcript Slide1: MuCap High-Precision Measurement of Muon Capture on the Proton University of California, Berkeley (UCB and LBNL) Petersburg Nuclear Physics Institute Paul Scherrer Institut University of Illinois, Urbana-Champaign Universite Catholique de Louvain TU Munich University of Kentucky Boston University Tom Banks APS DNP Fall Meeting 1 November 2003Experimental Goal: Experimental Goal Our goal is to measure the rate Λs of muon capture on the proton to 1% precision. This is a semileptonic weak interaction process, and (in our experiment) capture occurs predominantly from the hyperfine singlet atomic bound state. A 1% measurement of Λs determines gp – the “weak nucleonic charged current induced pseudoscalar form factor” – to < 7% precision. gp is the least well-known of the weak nucleonic c.c. form factors, and there is significant disagreement among previous gp measurements, and theory.Experimental Technique: Experimental Technique “Lifetime” or “Disappearance” Method For μ– in hydrogen, muon capture competes with muon decay: This rate competition decreases the observed μ– lifetime from the vacuum lifetime, which we measure separately with μ+ :Experimental Technique: Experimental Technique “Lifetime” or “Disappearance” Method Since our experiment can only observe the decay products e+ and e–, muon capture produces a small downward deflection of the μ– lifetime curve from the μ+ “vacuum” lifetime curve : The capture rate is easily calculated from the measured lifetimes: counts time μ+ μ – How Is This Experiment Superior?: How Is This Experiment Superior? High Statistics: In order to measure ΛS to 1% precision, we intend to measure both μ+ and μ– lifetimes to the level of 10 ppm, which requires recording 1010 decay events for each species. This is possible through our unique combination of detectors and analysis capabilities. Improved Target: We use 10 bar, ultra-pure protium gas (impurities at 10–8 level, deuterium-depleted H2 to 1 ppm). This eliminates molecular formation complications, and dramatically reduces distortions in the lifetime histograms. Experimental Setup – Apparatus: Experimental Setup – Apparatus entrance scintillator (t = 0) muPC1 muPC2 TPC ePC2 ePC1 eSC (Hodoscope) μ beam Muon Detectors Electron Detectors2003 Experimental Run: 2003 Experimental Run The MuCap experiment is conducted at the Paul Scherrer Institut (PSI) near Zürich, CH. We spent March → August 2003 assembling experiment; recorded data from September → mid-October.2003 Experimental Run: In spite of its technical complexity, MuCap is running and has achieved some excellent first physics results: 2003 Experimental Run First combined assembly of muon detectors (including functional TPC), electron detectors, and high-speed DAQ. We performed extensive systematic checks on the detectors. 2003 Experimental Run: 2003 Experimental Run We achieved gas impurity levels of 10–7, as determined from software analysis... ... impurity capture events are visible in the TPC data. We also performed an intentional nitrogen-doped run (few ppm), for precision calibration.2003 Experimental Run: 2003 Experimental Run From September 25 → October 8 we estimate to have recorded ~ 109 good μ– TPC stops. We will spend the coming year analyzing this data and extract a 10% measurement of Λs.Slide11: lOP (ms-1) cP-Theory RMC mCap proposed exp theory update from Gorringe & Fearing gp OMC Saclay In situ gas cleaning and quality monitoring TPC should reach full voltage and see decay electrons ePC2 will be completed, allowing for electron track vectorization 1010 muon stops Outlook 2004 2003 Experimental Run – Limitations: 2003 Experimental Run – Limitations Poor muon stopping fraction: We expected to stop ~ 80% of all incident muons in the TPC. Instead, we observed (at best) good muon stops only 32% of the time. The reasons for this discrepancy are still being explored. Muon beam stopping distribution inside TPC z Initial beam stop profile, with all muon detectors in place. Note the large low momentum scattering in the tail of the beam. Stopping fraction was ~ 20%. Final beam stop profile, following the removal of muPC1– the stopping fraction improved to 32%. Note the improved Gaussian shape. This has called into question the utility of muPC1,2.