Axial-vector mass MA and K2K Q2 distribution

Slides:

Advertisements

Similar presentations

HARP Anselmo Cervera Villanueva University of Geneva (Switzerland) K2K Neutrino CH Meeting Neuchâtel, June 21-22, 2004.

Advertisements

Experimental Status of Deuteron F L Structure Function and Extractions of the Deuteron and Non-Singlet Moments Ibrahim H. Albayrak Hampton University.

14 Sept 2004 D.Dedovich Tau041 Measurement of Tau hadronic branching ratios in DELPHI experiment at LEP Dima Dedovich (Dubna) DELPHI Collaboration E.Phys.J.

MINERvA Overview MINERvA is studying neutrino interactions in unprecedented detail on a variety of different nuclei Low Energy (LE) Beam Goals: – Study.

Recent Electroweak Results from the Tevatron Weak Interactions and Neutrinos Workshop Delphi, Greece, 6-11 June, 2005 Dhiman Chakraborty Northern Illinois.

F.Sanchez (UAB/IFAE)ISS Meeting, Detector Parallel Meeting. Jan 2006 Low Energy Neutrino Interactions & Near Detectors F.Sánchez Universitat Autònoma de.

Howard Budd, Univ. of Rochester1 Vector and Axial Form Factors Applied to Neutrino Quasi-Elastic Scattering Howard Budd University of Rochester (in collaboration.

Un-ki Yang, Manchester 1 Nuclear Effects in Electron Scattering Arie Bodek University of Rochester Un-ki Yang University of Manchester NuFact 2008, Valencia,

Arie Bodek, Univ. of Rochester1 Vector and Axial Form Factors Applied to Neutrino Quasi-Elastic Scattering Howard Budd University of Rochester

Arie Bodek, Univ. of Rochester1 [P13.011] Modeling Neutrino Quasi-elastic Cross Sections Using Up.

New results from K2K Makoto Yoshida (IPNS, KEK) for the K2K collaboration NuFACT02, July 4, 2002 London, UK.

Atmospheric Neutrino Oscillations in Soudan 2

Shoei NAKAYAMA (ICRR) for Super-Kamiokande Collaboration December 9, RCCN International Workshop Effect of solar terms to  23 determination in.

1 Super-Kamiokande atmospheric neutrinos Results from SK-I atmospheric neutrino analysis including treatment of systematic errors Sensitivity study based.

MINERvA Overview MINERvA is studying neutrino interactions in unprecedented detail on a variety of different nuclei Low Energy (LE) Beam Goals: – Study.

Measurements of F 2 and R=σ L /σ T on Deuteron and Nuclei in the Nucleon Resonance Region Ya Li January 31, 2009 Jlab E02-109/E (Jan05)

W properties AT CDF J. E. Garcia INFN Pisa. Outline Corfu Summer Institute Corfu Summer Institute September 10 th 2 1.CDF detector 2.W cross section measurements.

5th International Conference on Hyperons, Charm and Beauty Hadrons, Vancouver David Waller, Carleton University Ottawa, Canada Semileptonic BR of b hadrons.

Recent results from the K2K experiment Yoshinari Hayato (KEK/IPNS) for the K2K collaboration Introduction Summary of the results in 2001 Overview of the.

The Muon Neutrino Quasi-Elastic Cross Section Measurement on Plastic Scintillator Tammy Walton December 4, 2013 Hampton University Physics Group Meeting.

12 February 2003 M.Sakuda Neutrino － Nucleus Interactions Low Energy Neutrino-Nucleus Interactions Makoto Sakuda (KEK) in collaboration with C.Walter,

ENHANCED DIRECT PHOTON PRODUCTION IN 200 GEV AU+AU IN PHENIX Stefan Bathe for PHENIX, WWND 2009.

K2K NC  0 production Shoei NAKAYAMA (ICRR, Univ. of Tokyo) for the K2K Collaboration July 28, NuFact04.

Kalanand Mishra April 27, Branching Ratio Measurements of Decays D 0  π - π + π 0, D 0  K - K + π 0 Relative to D 0  K - π + π 0 Giampiero Mancinelli,

Latest Results from the MINOS Experiment Justin Evans, University College London for the MINOS Collaboration NOW th September 2008.

Measurements of neutrino charged current scattering in K2K Fine-Grained Detector Introduction Introduction K2K Near Detector K2K Near Detector CC interactions.

NuFact02, July 2002, London Takaaki Kajita, ICRR, U.Tokyo For the K2K collab. and JHF-Kamioka WG.

Total photoabsorption on quasi free nucleons at 600 – 1500 MeV N.Rudnev, A.Ignatov, A.Lapik, A.Mushkarenkov, V.Nedorezov, A.Turinge for the GRAAL collaboratiion.

Nucleon Decay Search in the Detector on the Earth’s Surface. Background Estimation. J.Stepaniak Institute for Nuclear Studies Warsaw, Poland FLARE Workshop.

Neutrino cross sections in few hundred MeV energy region Jan T. Sobczyk Institute of Theoretical Physics, University of Wrocław (in collaboration with.

JPS 2003 in Sendai Measurement of spectral function in the decay 1. Motivation ~ Muon Anomalous Magnetic Moment ~ 2. Event selection 3. mass.

1 Constraining ME Flux Using ν + e Elastic Scattering Wenting Tan Hampton University Jaewon Park University of Rochester.

Preliminary Results for CCQE Scattering with the MINOS Near Detector Mark Dorman, UCL On behalf of the MINOS Collaboration NUINT 09, CC/NC QE Scattering,

April 26, McGrew 1 Goals of the Near Detector Complex at T2K Clark McGrew Stony Brook University Road Map The Requirements The Technique.

K2K near detector: Measurement of the  flux in absence of oscillations and of the beam direction 3 different detectors: 1 Kton Water Čerenkov: Small replica.

Comparison of quasi-elastic cross sections using spectral functions with (e,e') data from 0.5 GeV to 1.5 GeV Hiroki Nakamura (Waseda U). Makoto Sakuda.

1 Measurement of the Mass of the Top Quark in Dilepton Channels at DØ Jeff Temple University of Arizona for the DØ collaboration DPF 2006.

Ibrahim H. Albayrak, Hampton University Group Meeting Experiment Rosen07: Measurement of R =  L /  T on Deuterium in the Nucleon Resonance Region. 

Simultaneous photo-production measurement of the  and  mesons on the nucleons at the range 680 – 1500 MeV N.Rudnev, V.Nedorezov, A.Turinge for the GRAAL.

Kalanand Mishra June 29, Branching Ratio Measurements of Decays D 0  π - π + π 0, D 0  K - K + π 0 Relative to D 0  K - π + π 0 Giampiero Mancinelli,

Results and Implications from MiniBooNE: Neutrino Oscillations and Cross Sections 15 th Lomonosov Conference, 19 Aug 2011 Warren Huelsnitz, LANL

September 10, 2002M. Fechner1 Energy reconstruction in quasi elastic events unfolding physics and detector effects M. Fechner, Ecole Normale Supérieure.

Belle General meeting Measurement of spectral function in the decay 1. Motivation 2. Event selection 3. mass spectrum (unfolding) 4. Evaluation.

Measurement of the Muon Charge Ratio in Cosmic Ray Events with the CMS Experiment at the LHC S. Marcellini, INFN Bologna – Italy on behalf of the CMS collaboration.

Neutrino Interaction measurement in K2K experiment (1kton water Cherenkov detector) Jun Kameda(ICRR) for K2K collaboration RCCN international workshop.

Upsilon production and μ-tagged jets in DØ Horst D. Wahl Florida State University (DØ collaboration) 29 April 2005 DIS April to 1 May 2005 Madison.

MINERνA Overview  MINERνA is studying neutrino interactions in unprecedented detail on a variety of different nuclei  Low Energy (LE) Beam Goals: t Study.

Inclusive jet photoproduction at HERA B.Andrieu (LPNHE, Paris) On behalf of the collaboration Outline: Introduction & motivation QCD calculations and Monte.

Path forward: theory vs experiment needs, QE discussion input Comments/Observations: R. Tayloe, Nuint'09.

IBD Detection Efficiencies and Uncertainties

Jun Kameda (ICRR) RCCN International workshop at Kashiwa (Dec.10,2004)

Matteo Negrini Frascati, Jan 19, 2006

Charged Current Cross Sections with polarised lepton beam at ZEUS

Quasielastic Scattering at MiniBooNE Energies

F.Sánchez for the K2K collaboration UAB/IFAE

Observation of Diffractively Produced W- and Z-Bosons

p0 life time analysis: general method, updates and preliminary result

Nadia Fomin University of Virginia

A New Measurement of |Vus| from KTeV

presented by Werner Boeglin Florida International University Miami

Study of Strange Quark in the Nucleon with Neutrino Scattering

Fine-Grained Near Detector(s) at JHF: Purpose and Thoughts

Neutrino interaction measurements in K2K SciBar

Impact of neutrino interaction uncertainties in T2K

Study of e+e- pp process using initial state radiation with BaBar

Study of e+e collisions with a hard initial state photon at BaBar

NKS2 Meeting with Bydzovsky NKS2 Experiment / Analysis Status

Charged Current Cross Sections with polarised lepton beam at ZEUS

Observation of Diffractively Produced W- and Z-Bosons

GEp-2γ experiment (E04-019) UPDATE

Presentation transcript:

Axial-vector mass MA and K2K Q2 distribution Makoto Sakuda (Okayama) 22 June, 2005 @ NuFact05 Outline 1. MA analysis with SciFi detector data R.Gran’s paper published in NuInt04 (NPB(Proc.Suppl.)139) M.Hasegawa et al.(K2K), --F.Sanchez’s talk 2. Summary Discussion Session Review of the method to estimate the quasi-elastic cross section and the axial-vector mass MA 22 June 2005 M.Sakuda@NuFact05

MA analysis with K2K SciFi detector data Previous MA analyses generally used Dipole form for vector form factors Q2>0.2 (GeV/c)2 to avoid the nulcear effect - Fermi-Gas model for nucleus (Deuteron wave function calculation for deuteron data) shows it. In this analysis, we studied carefully the following effects: Effect of the new vector form factor measurements Effect of the energy scale (detector dep.) 1%~MA±0.05. This may have been overlooked before. Effect of background shape (1p) from data Proton rescattering –This is relevant to our QE/nQE separation Flux uncertainty and event migration 22 June 2005 M.Sakuda@NuFact05

and form factors 1. Quasi-elastic cross section nm nm- p Form Factors F1V,F2V,and FA and (s-u)=4MEn-Q2-Mm2 A = Q2/4M2 [(4 + Q2/M2)|FA|2 - (4 - Q2/M2)|FV1|2 + Q2/M2(1-Q2/4M2)|xFV2|2+ 4Q2/M2xReFV*1FV2 　　 -m2/4M2 (| FV1 + FV2 |2 + | FV1 +2Fp |2 –4(1+t) |Fp|2] B = -Q2/M2ReF*A(FV１ + xFV２), C = 1/4(|FA|2 + |FV1|2 + Q2/4M2|xFV2|2). Historically, we used Vector Form factors 　GEp=D, GMp=mpD, GMn=mnD, GEn=-mnt/(1+lt)D, D=1/(1+Q2/MV2)2, MV=0.843 (GeV/c2) mp=2.792847, mn=-1.913043, l=5.6, t= Q2/4M2 Axial-vector form factor FA FA(Q2)=-1.2617/(1+Q2/MA2)2 22 June 2005 M.Sakuda@NuFact05

Nucleon Form Factors　　　 Electromagnetic current (Jaem) and weak hadronic charged current (JaCC=Va1+i2–Aa1+i2) is written in terms of form factors: e e q N N 22 June 2005 M.Sakuda@NuFact05

(includes normalization) dQE/dQ2 distribution at En = 1.3 GeV ddq2(10-38cm2/(GeV/c)2) MA=1.2 GeV MA=1.1 GeV MA=1.0 GeV Absolute Cross-section (includes normalization) Q2(GeV/c)2 MA=1.0 GeV MA=1.1 GeV MA=1.2 GeV Shape only Q2(GeV/c)2 22 June 2005 M.Sakuda@NuFact05

Nucleon Vector Form Factors Gourdin@Phys.Rep.C11(‘74) A simple dipole form GD = (1+Q2/MV2)-2, MV=0.843 was known to be good to only 10-20% level for vector Form Factors since 1970s. Gen looked finite. But, no one needed better accuracy than that with dipole forms, untill Neutrino physics need it recently. 22 June 2005 M.Sakuda@NuFact05

Updated Nucleon Vector Form Factors de Jager@PANIC02 A simple dipole form D=(1+Q2/MV2)-2, MV=0.843 GMnGMp  GEp Curve – Bosted, PRC51,409,’95 Curve=(1+a1Q+a2Q2+.+a5Q5)-1 E.J.Brash et al. , Phys.Rev.C65,051001(2002). Similar Neutrino cross section shape will change if we use these data. Q2 22 June 2005 M.Sakuda@NuFact05

ds/dQ2 vs. Q2 with new Vector Form Factors GMn,GMp,GEp ,GEN Old cross section (line) vs new (dot) Ratio of new cross section to old cross section. Eν = 1.0 MA= 1.1 +5% -4% New cross section is smaller at low Q2 and larger at higher Q2 ~5% overall difference in dsQE/dQ2 Fp is < 1% different, GEn is ~2% different, both largest at low Q2 Changes MA fit value by -0.05 22 June 2005 M.Sakuda@NuFact05

Message from here is: Axial vector form factor can be approximated by a dipole form only at 10-20% level as vector form factor was. If the accurate neutrino cross section is measured in 5-10 years, there is no need for MA in the future. We parameterize axial form factors in the same way. Discussion What formalism should be preferable? 22 June 2005 M.Sakuda@NuFact05

２．Reconstruction of Quasi-Elastic Neutrino Interactions from measured lepton angle and lepton momentum   θ q p Axial vector form factor depends on MA and Q2 22 June 2005 M.Sakuda@NuFact05

Scintillating Fiber (SciFi) detector -a Fine-grain detector with water target -It has operated since 1999 till the end of 2003 and measured flux To Muon Range Detector Muon in the Muon Range Detector must have pmuon > 600 MeV/c Recoil proton threshold is three layers in SciFi pproton > ~ 600 MeV/c 1-track events with muon only 2-track events with muon plus either proton or pion 22 June 2005 M.Sakuda@NuFact05

Event Selection  n-> - p Typical two-track event showing the muon and second track 1 track event 2 track event Neutrino interaction in H2O target (+ 20% Aluminum) 22 June 2005 M.Sakuda@NuFact05

Dq distribution of 2 track events: QE and nonQE  + n -> -+p - (E, p)  p Expected proton assuming QE interaction  use the location of proton track to separate events into three subsamples: 1-track (no proton) 60% QE 2-track QE enhanced 60% QE 2-track nQE 85% nonQE, 15% QE nonQE QE 22 June 2005 M.Sakuda@NuFact05

Basic Distributions, Pm, qm for Scifi Detector Overall agreement is good Pm qm Muon momentum Muon angle One-track events (60% QE) 22 June 2005 M.Sakuda@NuFact05

Reconstructed Q2 distribution in SciFi detector Make DIS correction (Bodek/Yang) and reduced Coherent Pion production (Marteau) 1 track sample 2 track QE enhanced 2 track non-QE 22 June 2005 Q2 (GeV/c)2 M.Sakuda@NuFact05 Q2 (GeV/c)2 Q2 (GeV/c)2

Fit only Q2 > 0.2 region Most significant uncertainties due to Pauli blocking and choice of nuclear model, coherent pion, correction to DIS -> Q2 cut Monte Carlo best fit Quasi Elastic fraction QE signal and inelastic background are treated the same way 22 June 2005 M.Sakuda@NuFact05 Reconstructed Q2 (GeV/c)2

Uncertainty in QE cross section due to Pauli Blocking in the Q2 < 0.2 region a Fermi-gas model with different Fermi-momenta kf Free nucleon (no Pauli Blocking) 210 kf = 225 235 MeV/c We Cut here 22 June 2005 M.Sakuda@NuFact05

Preliminary MA fit with K2K-I and K2K-IIa data MA = 1.18 +/- 0.03 stat +/- 0.12 syst Bodek/Yang DIS correction and Marteau Coherent Pi cross-section Fit the 1track, 2track (QE), and 2track (nonQE) simultaneously K2K-I 8114 events total 4310 Q2>0.2 in fit K2K-IIa 5967 events total 2525 Q2>0.2 in fit Reconstructed Q2 22 June 2005 1 Track M.Sakuda@NuFact05 2 Track QE 2 Track nQE

Systematic Errors in combined fit Flux and Normalization 0.08 Energy scale 0.04 LG density 0.02 Escale/LG correlation 0.04 Escale-MA correlation 0.03 MA-1pi 0.03 nQE/QE 0.03 Statistics 0.03 Total error 0.12 22 June 2005 M.Sakuda@NuFact05

MA vs Q2 cut value -- We use data for Q2>0.2 At low Q2 there are large nuclear effects (Pauli blocking) also uncertainty in coherent pion and multi-pion interactions. 1.06 Zero Coherent pion Lowers MA by 0.10 better Pauli Blocking 0.10 effect at Q2min=0.0 Standard Cut K2K-I data, MA-1p = 1.1 statistical errors and energy spectrum uncertainty Result is stable and consistent with MA=1.06 for cuts above Q2 = 0.2 But statistical errors dominate for high Q2 cuts This is the standard cut used by almost all the experiments. 22 June 2005 M.Sakuda@NuFact05

MA for different energy ranges The MA fit can be peformed separately for each energy range. They are consistent each other within 2s errors: QE cross sections are consistent with MA=1.06 (GeV/c2) at each energy. 1.06 Q2 cut = 0.2 statistical errors only 22 June 2005 M.Sakuda@NuFact05

Comparison of MA obtained by other experiments stat error total error (H2O) This experiment 1.06 +/- 0.03 stat +/- 0.14 syst. Dipole Form Factors Q2min. = 0.2 (GeV/c)2 Deuterium MAQE 1.0 22 June 2005 M.Sakuda@NuFact05

Conclusions We present the preliminary analysis of MAQE with SciFi detector (1999-2003) MA = 1.18 +/- 0.03 stat. +/- 0.12 syst. Here, we use Fermi Gas modl, the dipole form (MV=0.843) for vector form factors, and only data with Q2 > 0.2. We will give two values of MA, one with old vector form factors in order to compare with the old MA measurements, and the other with new vector form factors. MA becomes smaller by 0.05-0.07. ---------------------------------------------- Personal comment: In the near future, we need better parametrization for the quasi-elastic cross sections (single pion production) and better theoretical calculations over the entire q2 region, if we want to obtain the accuracy at a few % level. BodekVector form factors and nuclear effect will be measured. e+Ce+X. June 25 (WG2) Benhar, Varverde,BarbaroBetter calculation over the entire q2 region. Benhar et.al,hep-ph/0506116, to appear in PRD. 22 June 2005 M.Sakuda@NuFact05

Benhar et al., hep-ph/0506116, PRD, -Comparison of FG, SP, SP+FSI validated by electron scattering data FG SP SP+FSI 22 June 2005 M.Sakuda@NuFact05

Combined fit with the K2K-I data Q2 distribution, all energy bins combined, no Coherent Pion in MC Green shows the QE fraction Slide 4a 22 June 2005 M.Sakuda@NuFact05

Combined fit with the K2K-IIa data Q2 distribution, all energy bins combined, no Coherent Pion in MC Green shows the QE fraction Slide 4b 22 June 2005 M.Sakuda@NuFact05

Pauli Bloching effect En=1.3 GeV，kF=220 MeV/c ds/dQ2 n m- Nuclear effects are large in the low Q2 region, where the cross section is large. En=1.3 GeV，kF=220 MeV/c ds/dQ2 n m- Quasi-elastic q W/o Pauli effect n p P p W/ Pauli effect Total 8% ds/dQ2 0.5 1.0 If P <kF , suppressed. n m- D production 10-15% suppression At low Q2 Total 3% reduction q p D P p P p W 22 June 2005 M.Sakuda@NuFact05

Charged-Current Quasi-elastic Scattering This is the simplest and the most important reaction. Calculation by Ch.L.Smith et al. with MA=1.0. _ s(nm pm+ n) s(nm nm- p) 1.0 1x10-381.0 (cm2) Pauli effect ~8% 0. 0.1 1.0 10. 50. 0.1 1. 10. 22 June 2005 M.Sakuda@NuFact05

Single Pion Production Cross Section Prediction = Rein-Sehgal MA=1.2 GeV/c2 MS@nuint01 1x10-381.0 (cm2) 0.0 22 June 2005 M.Sakuda@NuFact05