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The physics Experimental challenges The proposal(s) Elementary reaction (& 16 O) Few body systems (  N, 4  H) Medium mass nuclei ( 40 Ca, 27 Al, 48 Ti)

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Presentation on theme: "The physics Experimental challenges The proposal(s) Elementary reaction (& 16 O) Few body systems (  N, 4  H) Medium mass nuclei ( 40 Ca, 27 Al, 48 Ti)"— Presentation transcript:

1 The physics Experimental challenges The proposal(s) Elementary reaction (& 16 O) Few body systems (  N, 4  H) Medium mass nuclei ( 40 Ca, 27 Al, 48 Ti) Heavy nuclei: 208 Pb Summary and conclusions A Study with High Precision on the Electro-production of the  and  -Hypernuclei in the Full Mass Range F. Garibaldi - PAC Jlab – 18 June 2013 Tohoku

2 HYPERNUCLEAR PHYSICS Hypernuclei are bound states of nucleons with a strange baryon (  ) Extension of physics on N-N interaction to system with S#0 Internal nuclear shell are not Pauli-blocked for hyperons Spectroscopy  -N interaction, mirror hypernuclei,CSB,  binding energy, limits of mean field description, the role of 3 body interaction in hypernucley and neutron stars…. Ideal laboratory to study This “impurity” can be used as a probe to study both the structure and properties of baryons in the nuclear medium and the structure of nuclei as baryonic many- body systems

3  N interaction (r) Each of the 5 radial integral (V, , S , S N, T) can be phenomenologically determined from the low lying level structure of p-shell hypernuclei V SS SNSN   ✔ most of information is carried out by the spin dependent part ✔ doublet splitting determined by ,  , T

4 The observation of a very heavy pulsar (M=1.97(4) solar masses, Demorest et al. Nature 467 1081 (2010), severely constraints the equation of state at high densities with implications for possible hypernuclear components. Further information on contributions of non nucleonic degrees of freedom from experiments are important

5 High resolution, high yield, and systematic study is essential using electromagnetic probe and BNL 3 MeV Improving energy resolution KEK336 2 MeV ~ 1.5 MeV new aspects of hyernuclear structure production of mirror hypernuclei energy resolution ~ 500 KeV 635 KeV

6 good energy resolution reasonable counting rates forward angle septum magnets do not degrade HRS minimize beam energy instability “background free” spectrum unambiguous K identification RICH detector High P k /high E in (Kaon survival)  E beam /E : 2.5 x 10 -5 2.  P/P : ~ 10 -4 3. Straggling, energy loss… ~ 600 keV

7 HKS PID (gas Cherenkof + shower counter) e,  rejection   HKS PID 3 TOF, 2 water Cherenkiv, three aerogel Cerenkov Power rejection capability is: - In the beam p:K:p 10000:1:2000 - in the on-line trigger 90:1:90 - after analysis it is 0.01:1:0.02 - so for  the rejection power is 10 6 - and for p 10 5 Elastic scattering measurement off Pb-208 to know the actual thickness of the target then monitor continuously by measuring the electron scattering rate as a function of two- dimensional positions by using raster information.  i  100 mg/cm cryocooling PID    (threshold + RICH) RICH Detector Targets standard solid + waterfall + solid cryocooled for Pb

8 Future mass spectroscopy Hypernuclear spectroscopy prospectives at Jlab Decay Pion Spectroscopy to Study  -Hypernuclei

9  Elementary production of  1 H  e,e’K  -Measure the elementary production cross section as input for hypernuclear calculations and determine the small angle behavior of the angular distribution. - Calculations of the hypernuclear cross section use the elementary amplitudes and a nuclear and hypernuclear wavefunction. - By measuring the ratio of hypernuclear/elementary reaction makes the interpretation simpler -the cross sections for the electroproduction of hypernuclei are sensitive only to the elementary amplitude for very small kaon angles. unexplored -The elementary reaction itself is also interesting in this unexplored kinematics region.

10 Be windows H 2 O “foil”    “ foil ” WATERFALL The WATERFALL target: reactions on 16 O and 1 H nuclei

11 1 H (e,e’K)  16 O(e,e’K) 16 N  1 H (e,e’K)    Energy Calibration Run Results on the WATERFALL target - 16 O and 1 H  Water thickness from elastic cross section on H  Precise determination of the particle momenta and beam energy using the  and  peak reconstruction (energy scale calibration)

12 10/13/09 study the angular dependence of p(e,e’K)  and 16 O(e,e’K) 16 N  at low Q 2 R esults on H target – The p(e,e’K)  C ross S ection  None of the models is able to describe the data over the entire range   New data in electroproduction allows studying dynamics of the models – hadronic form factors, longitudinal couplings….. W  GeV The small angle behavior of the cross section is poorly known results from E94-107 running at higher W). CLAS, SAPHIR and LEPS have difficulty reaching angles smaller than ~20 o. This experiment will cover the range   ~ 0 and allow for several bins.

13 magnetstarget energy resolution ANDParticle Identification unique opportunity hypernuclear process AND elementary process Septum magnets, waterfall target, excellent energy resolution AND Particle Identification ) give unique opportunity to measure, simultaneously, hypernuclear process AND elementary process The models for the K + -  electromagnetic production on protons differ drastically, therefore the interpretation of the hypernuclear spectra (cross sections) is difficult because of the lack of relevant information about the elementary process The ratio of the hypernuclear and elementary cross section measured at the same kinematics is almost model independent at very forward kaon scattering angles The ratio of the hypernuclear and elementary cross section doesn’t depend strongly on the electroproducion model and contains direct information on hypernuclear structure and production mechanism The ratio of the hypernuclear and elementary cross section doesn’t depend strongly on the electroproducion model and contains direct information on hypernuclear structure and production mechanism

14 Dividing up by the elementary cross section allows to remove the strong angular dependence in the hypernuclear cross section The remaining angular dependence comes mainly from the nuclear hypernuclear sructure In the doublet case the sipn flip part is coupled in different way to the members (elementary part)

15 Few body sytems the  N interaction and [  n] bound state precise precise few-body calculation techniques allow us to study the  N interaction with less ambiguity Experiment at GSI (  n invariant mass enhancement) the experimental resolution were limited in the experiment. Most of the theoretical models predict no  n bound state The 2D(e,e’K+)[  n] reaction can clarify that This experiment could be done with 72 hours of beam time to put an upper limit (5  sensitivity (0.5 nb/sr))

16 This  coupling selectively increases the binding energies of the 0+ ground states of the A=4 hypernuclei and is thereby also responsible for about half of the spacing between the 1+ and 0+ states. CHARGE SYMMETRY BREAKING the s-shell hypernuclei ( 3  H, 4  H, 4  He 4, and 5  He) exactly can be treated exactly by few-body techniques (Fadeev etc) Importance of  coupling (binding energies) Importance of the three body interaction, not included in few body calculations (and doesn’t contribute directly on CSB of A = 4 systems) Comparison with ab initio coherent Mcarlo microscopic calculations that include the 3 body interactions in the entire A range

17 To have 500 events in the g.s. ~ 263 hours of beam time Assuming 12.36 nb/sr (E-91- 016) and scaling the c.r. from 12  B (normalized to the target thickness (500 mg/cm2)), 10  A beam

18 Medium heavy hypernuclei  to what extent does a Λ hyperon keep its identity as a baryon inside a nucleus?”  the mean-field approximation and the role that the sub-structure of nucleons plays in the nucleus.  the existing data from (π+, K + ) reactions obtained at KEK, do not resolve the fine structure in the missing mass spectra due to limited energy resolution (a few MeV), and theoretical analyses suffer from those uncertainties  the improved energy resolution (600 ∼ 800keV) of (e,e’K) hypernuclear spectroscopy, which is comparable to the spreading widths of the excited hypernuclear states, will provide important information

19 - The mass (A) dependence of the central binding potential depth from the absolute Λ binding energies - Information about the spin-orbit splitting as a function of the core nucleus mass - Self-consistent interaction parameters for non-relativistic Hartree-Fock or relativistic mean-field theories. - Access to deformation of the core nucleus, utilizing the  as a probe. Modify energy levels of a core nucleus by adding a  as an impurity.

20 complete A dependence in the medium mass region 40  K is clean, since the 40 Ca is doubly LS-closed up to the 0d3/2 shell. A precise mass spectrum of 40  K will complete the A dependence of  single energies in the medium mass region There is a variety of isotopes (Ca40, Ca44, Ca48) This will allow for the first time to study hypernuclear isotopes sistematically. Comparison of  binding eneries Collective deformation plays an important rolee in sd-shell nuclei. Triaxial deformation is expected for Mg- 26 Deformation properties never studied for hypernculei, some observation for Be

21 Does the  affect the core structure? Energy levels inversion Ground state degenerate, but different deformations.  might separate these states by different copupling to parity states. Pushed up adding a , level order between positive and negative parity states changed Precise spectroscopy of 27  Mg will make clear the triaxially deformed Mg structure and characteristic hypernnuclear states, this is possible because  doesn’t suffer for Pauli blocking

22   Hyperon in heavier nuclei – 208 (e,e’K+) 208  Ti ✔ A range of the mass spectroscopy to its extreme ✔ Distinguishability of the hyperon in the nuclear medium ✔ Studied with ( ,k) reaction, levels barely visible (poor energy resolution) ✔ (e,e’K) reaction can do much better. Energy resolution  Much more precise  single particle energies. Complementarity with ( ,k) reaction ✔ the mass dependence of the binding energy for each shell model orbital will be extended to A = 208, where the ambiguity in the relativistic mean field theories become smaller. ✔ neutron stars structure and dynamics

23   Hyperon in heavier nuclei – 208 (e,e’K+) 208  Ti Hotchi et al., PRC 64 (2001) 044302 Hasegawa et. al., PRC 53 (1996)1210 Measured ( ,K)

24 Separation energy as a function of the baryon number A. Plain green dots [dashed curve] are the available B  experimental values. Empty red dots [upper banded curve] refer to the AFDMC results for the nuclear AV4' potential plus the two-body  N interaction alone. Empty blue diamonds [lower banded curve] are the results with the inclusion of the three-body hyperon-nucleon force. Lonardoni et al. Role of the two- and three-body hyperon-nucleon interaction in – hypernuclei,(arXiv:1301.7472v1 [nucl-th] 30 Jan 2013)

25 Appearence of hyperons brings the maximum mass of a stable neutron star down to values incompatible with the recent observation of a star of about two solar masses. It clearly appears that the inclusion of YNN forces leads to a large increase of the maximum mass, although the resulting value is still below the two solar mass line. It is a motivation to perform more realistic and sophisticated studies of hyperonic TBF and their effects on the neutron star structure and dynamics, since they have a pivotal role in this issue It seems that only simultaneous strong repulsion in all relevant channels could significantly raise the maximum mass

26 Millener-Motoba calculations - particle hole calulation, weak-coupling of the  hyperon to the hole states of the core (i.e. no residual  -N interaction)  - Each peak does correspond to more than one proton-hole state - Interpretation will not be difficult because configuration mixing effects should be small - Comparison will be made with many-body calculations using the Auxiliary Field Diffusion Monte Carlo (AFDMC) that include explicitely the three body forces. - Once the  single particle energies are known the AMDC can be used to try to determine the balance between the spin dependent components of the  N and  NN interactions required to fit  single- particle energies across the entire periodic table.

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28 Beam time request TargetBeam time (hours) waterfall168 d72 4He263 Medium mass840 208Pb840 Total 2183

29 Summary and conclusions - The (e,e’K) experiments performed at Jlab in the 6 GeV era confirmed the specific, crucial role of this technique in the framework of experiments performed and planned in other facilities. ✔ The study of few body will provide important information about Charge Symmetry Breaking.  N interaction - Charge Symmetry Breaking (CSB) in the Λ-N interaction - Limits of the mean field description of nuclei and hypernuclei - Λ binding energy as a function of A for different nuclei than those probed with hadrons and structure of tri-axially deformed nucleus using a Λ as a probe. - Energy level modification effects by adding a Λ - The role of the 3 body ΛNN interaction in Hypernuclei and Neutron Stars The new experiments will allow to get important information on

30 Summary and conclusions ✔ The of hypernculear physics is an important part of the modern nuclear and hadronic physics ✔ The (e,e’K) experiments performed at Jlab in the 6 GeV era confirmed the specific, crucial role of this technique in the framework of experiments performed and planned in other facilties. ✔ The study of the elementary part of the reaction is important. The proposed angular distribution study will allow to answer the following questions: - does the cross section for the photo-production continue in rising as the kaon angle goes to zero or is there a plateau or even a dip like for the high energy data? - what is the angular dependence of the hypernuclear form factor at forward angle  is the hypernuclear angular dependence the same as the hypernuclear process? ✔ The study of few body will provide important information about Charge Symmetry Breaking. ✔ Interesting comparison betwen theory and different kind of calculations, namely lattice QCD calulations, standard Mcarlo calulation, ab initio Mcalrlo calculations possible in the entire A range ✔ Confirmation of non existence or the existence of a  n bound state will be established

31 ✔ The study of medium and heavy hypernuclei is an essential part of the series of measurements we propose, fully complementary to what performed and proposed with (e,e’K) reactions and in the framework of experiments performed or planned at other facilities ✔ Important information will be obtained on the limits of the description of hypernculei and nuclei in terms of shell model/mean field approximation ✔ The crucial role of three body interaction both in hypernuclei and in the structure and dynamics of neutron stars will be shown ✔ The behaviour of  binding energy as function of A will be extended at his extreme ✔ Comparison between standard shell/model-mean field calculations and microscopic Mcarlo consistent calculations will show their valididy in the whole A range ✔ Comparison of (e,e’K) with ( ,K) results might reveal the limits of the distinguishability of the hyperon in the dense nuclear medium ✔ Combining the informations from the performed and proposed (e,e’K) experiment will allow a step forward in the comprehension of the role of the strangeness in our world.

32 In terms of mesons and nucleons: Or in terms of quarks and gluons: V = Understanding the N-N Force

33 Hypernuclei Provide Essential Clues For the N-N System: For the  N System:

34 ELECTROproduction of hypernuclei e + A -> e’ + K + + H in DWIA (incoming/outgoing particle momenta are ≥ 1 GeV) - J m (i) elementary hadron current in lab frame (frozen-nucleon approx) -   virtual-photon wave function (one-photon approx, no Coulomb distortion) -   – distorted kaon w. f. (eikonal approx. with 1 st order optical potential) -      - target nucleus (hypernucleus) nonrelativistic wave functions (shell model - weak coupling model)

35 hadron arm septum magnets RICH Detector electron arm aerogel first generation aerogel second generation To be added to do the experiment Hall A deector setup

36 Hall C (HKS, HES, ENGE)

37 ✓ p(e,e′K+)  The data suggest that not only do the present models fail to describe the data over the full angular range, but that the cross section rises at the forward angles. The failure of existing models to describe the data suggests the reaction mechanisms may be incomplete. ✓ 7 Li(e,e’k) 7  He A clear peak of the 7 He ground state for the first time. CSB term puzzle experiment and theory worse, (CSB term is essential for A=4 hypernuclei).  understanding of the CSB effect in the  interaction potential is still imperfect. ✓ 9 Be(e,e’K+) 9  Li: Disagreement between the standard model of p-shell hypernculei and the measurements, both for the position of the peaks and for the cross section. ✓ 12 C(e,e’K+) 12  B: for the first time a measurable strength with sub-MeV energy resolution has been observed in the core-excited part of the spectrum. The s part of the spectrum is well reproduced by the theory, the p shell part isn’t. ✓. 16 O(e,e’K+) 16  N: The fourth peak ( in p state) position disagrees with theory. This might be an indication of a large spin-orbit term S . Binding Energy B  =13.76±0.16 MeV measured for the first time with this level of accuracy

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39 Normalizing the cross section to the 2 - state the angular dependence is the same for the three states. This means the angular dependence is given by a genreal nuclera/hypernculear form factor

40 PurposeEnergyTime Calibrations 24 hours 8.5° 11° 36 hours 110 hours Total 170 hours Beam time request

41 806 hours + 34 hours for CH2 calibration  840 hours 5 weeks

42 YN, YY Interactions and Hypernuclear Structure Free YN, YY interaction Constructed from limited hyperon scattering data (Meson exchange model: Nijmegen, Julich ) YN, YY effective interaction in finite nuclei (YN G potential) Hypernuclear properties, spectroscopic information from structure calculation (shell model, cluster model… ) Energy levels, Energy splitting, cross sections Polarizations, weak decay widths high quality (high resolution & high statistics) spectroscopy plays a significant role G-matrix calculation

43 Goals of the proposal(s). Elementary kaon electroproduction. Spectroscopy of light Λ-Hypernuclei. Spectroscopy of medium-heavy Λ-Hypernuclei. Spectroscopy of heavy Λ-Hypernuclei They provide invaluable information on -  N interaction - Charge Symmetry Breaking (CSB) in the Λ-N interaction - Limits of the mean field description of nuclei and hypernuclei - Λ binding energy as a function of A for different nuclei than those probed with hadrons and structure of tri-axially deformed nucleus using a Λ as a probe. - Energy level modification effects by adding a Λ - The role of the 3 body ΛNN interaction in Hypernuclei and Neutron Stars

44 the information from the hypernucleus production is reacher than the ordinary elementary cross section the information from the hypernucleus production, when the cross sections for productionof various states are measured, is reacher than the ordinary elementary cross section Measuring the angular dependence of the hypernuclear cross section we may discriminate among models for the elementary process. Deviations in angular distribution would imply we have problems awith the wave functions

45  N vs  N “Therefore is of great importance to carry out accurate theoretical calculations of hypernuclear matter and the corresponding hyperon star structure, as much as possible constrained by independent experimental information on the hyperon-nucleon interactions.” H. J Schulze and T Rjiken, Phys Rev C84, 035801 (2011) New potential (ESC08) and TBF stiffen the EOS, allowing for higher maximum masses of hyperon stars. massive neutron stars have to be hybrid stars containing a core of nonbaryonic (“quark”) matter, since the possibility of them being nucleonic stars is ruled out by the early appearance of hyperons  appears earlier than 

46  i  100 mg/cm 2 cryocooling PID   (threshold + RICH) The target RICH Detector Target calibration and monitoring Elastic scattering measurement off Pb-208 to know the actual thickness of the target then monitor continuously by measuring the electron scattering rate as a function of two-dimensional positions by using raster information.

47 Precise spectroscopy of 27  Mg will make clear the triaxially deformed Mg structure and characteristic hypernnuclear states, this is possible because  doesn’t suffer for Pauli blocking


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