Nucleon PDF inside Compressed Nuclear Matter Jacek Rozynek NCBJ Warsaw ‘‘Is it possible to maintain my volume constant when the pressure increases?” -

Slides:

Advertisements

Similar presentations

Survey of Issues Misak Sargsian Florida International University.

Advertisements

Toshiki Maruyama (JAEA) Nobutoshi Yasutake (Chiba Inst. of Tech.) Minoru Okamoto (Univ. of Tsukuba & JAEA ) Toshitaka Tatsumi (Kyoto Univ.) Structures.

HL-3 May 2006Kernfysica: quarks, nucleonen en kernen1 Outline lecture (HL-3) Structure of nuclei NN potential exchange force Terra incognita in nuclear.

Hard Photon Production in a Chemically Equilibrating QGP at Finite Baryon Density Zejun He Zejun He Shanghai Institute of Applied Physics Research Chinese.

Hyperon-Quark Mixed Phase in Compact Stars T. Maruyama* (JAEA), T. Tatsumi (Kyoto U), H.-J. Schulze (INFN), S. Chiba (JAEA)‏ *supported by Tsukuba Univ.

Nuclear Physics from the sky Vikram Soni CTP. Strongly Interacting density (> than saturation density) Extra Terrestrial From the Sky No.

1 Transport and Hydrodynamic Model for Ultra-relativistic Heavy Ion Collisions Yu-Liang Yan China Institute of Atomic Energy Collaborators: Yun Cheng (CCNU,

Degree of polarization of  produced in quasielastic charge current neutrino-nucleus scattering Krzysztof M. Graczyk Jaroslaw Nowak Institute of Theoretical.

First Results From a Hydro + Boltzmann Hybrid Approach DPG-Tagung, Darmstadt, , Hannah Petersen, Universität Frankfurt.

DNP03, Tucson, Oct 29, Kai Schweda Lawrence Berkeley National Laboratory for the STAR collaboration Hadron Yields, Hadrochemistry, and Hadronization.

Xia Zhou & Xiao-ping Zheng The deconfinement phase transition in the interior of neutron stars Huazhong Normal University May 21, 2009 CSQCD Ⅱ.

Metastability of Hadronic Compact Stars I. Vidaña & I. Bombaci, P. K. Panda, C. Providência “The Complex Physics of Compact Stars” Ladek Zdroj, Poland,

P461 - Nuclei I1 Properties of Nuclei Z protons and N neutrons held together with a short-ranged force  gives binding energy P and n made from quarks.

Freeze-Out in a Hybrid Model Freeze-out Workshop, Goethe-Universität Frankfurt Hannah Petersen.

Eli Piasetzky Tel Aviv University, ISRAEL Short Range Correlations and the EMC Effect Work done in collaboration with: L. B. Weinstein (ODU) D. Higinbotham,

A Crust with Nuggets Sanjay Reddy Los Alamos National Laboratory Jaikumar, Reddy & Steiner, PRL 96, (2006) SQM, UCLA, March (2006)

5-12 April 2008 Winter Workshop on Nuclear Dynamics STAR Particle production at RHIC Aneta Iordanova for the STAR collaboration.

Modification of scalar field inside dense nuclear matter.

DPG spring meeting, Tübingen, March Kai Schweda Lawrence Berkeley National Laboratory for the STAR collaboration Recent results from STAR at RHIC.

Equation of State of Neutron-Rich Matter in the Relativistic Mean-Field Approach Farrukh J. Fattoyev My TAMUC collaborators: B.-A. Li, W. G. Newton My.

Dilepton production in HIC at RHIC Energy Haojie Xu( 徐浩洁 ) In collaboration with H. Chen, X. Dong, Q. Wang Hadron2011, WeiHai Haojie Xu( 徐浩洁 )

The structure of neutron star by using the quark-meson coupling model Heavy Ion Meeting ( ) C. Y. Ryu Soongsil University, Korea.

The Nucleon Structure and the EOS of Nuclear Matter Jacek Rozynek INS Warsaw Nuclear Physics Workshop KAZIMIERZ DOLNY 2006.

Glauber shadowing at particle production in nucleus-nucleus collisions within the framework of pQCD. Alexey Svyatkovskiy scientific advisor: M.A.Braun.

Isospin effect in asymmetric nuclear matter (with QHD II model) Kie sang JEONG.

1 On the importance of nucleation for the formation of quark cores inside compact stars Bruno Werneck Mintz* Eduardo Souza Fraga Universidade Federal do.

Enke Wang (Institute of Particle Physics, Huazhong Normal University) with A. Majumder, X.-N. Wang I. Introduction II.Quark Recombination and Parton Fragmentation.

QUARK MATTER SYMMETRY ENERGY AND QUARK STARS Peng-cheng Chu ( 初鹏程 ) (INPAC and Department of Physics, Shanghai Jiao Tong University.

Modeling the Hadronization of Quark Matter G. Toledo Sánchez Instituto de Fisica UNAM, Mexico A. Ayala, G. Paic, M. Martinez ICN-UNAM, México Strangeness.

Shanghai Elliptic flow in intermediate energy HIC and n-n effective interaction and in-medium cross sections Zhuxia Li China Institute of Atomic.

Nuclear Forces at Short Distances and the Dynamics of Neutron Stars Nuclear Forces at Short Distances and the Dynamics of Neutron Stars.

Chiral Symmetry Restoration and Deconfinement in QCD at Finite Temperature M. Loewe Pontificia Universidad Católica de Chile Montpellier, July 2012.

Higher moments of net-charge multiplicity distributions at RHIC energies in STAR Nihar R. Sahoo, VECC, India (for the STAR collaboration) 1 Nihar R. Sahoo,

N* Production in α-p and p-p Scattering (Study of the Breathing Mode of the Nucleon) Investigation of the Scalar Structure of baryons (related to strong.

Bjorken Scaling & modification of nucleon mass inside dense nuclear matter Jacek Rozynek INS Warsaw Nuclear Physics Workshop HCBM 2010.

Chiral phase transition and chemical freeze out Chiral phase transition and chemical freeze out.

Spin physics at the SMC Spin Muon Collaboration A. Magnon (CEA-Saclay/IRFU & COMPASS)

Role of vacuum in relativistic nuclear model A. Haga 1, H. Toki 2, S. Tamenaga 2 and Y. Horikawa 3 1. Nagoya Institute of Technology, Japan 2. RCNP Osaka.

Hadrons: color singlets “white states”

Color glass condensate in dense quark matter and off-diagonal long range order of gluons A. Iwazaki (Nishogakusha-u) Success of an effective theory of.

Quark-Gluon Plasma Sijbo-Jan Holtman.

CPOD2011 ， Wuhan, China 1 Isospin Matter Pengfei Zhuang Tsinghua University, Beijing ● Phase Diagram at finite μ I ● BCS-BEC Crossover in pion superfluid.

Nuclear Enthalpies J. Rozynek NCBJ Warszawa – arXiv nucl-th ( pedagogical example of volume/pressure corrections to EoS) ‘‘Is it possible to.

Three-body force effect on the properties of asymmetric nuclear matter Wei Zuo Institute of Modern Physics, Lanzhou, China.

Robert Pak (BNL) 2012 RHIC & AGS Annual Users' Meeting 0 Energy Ro Robert Pak for PHENIX Collaboration.

Hybrid proto-neutron stars within a static approach. O. E. Nicotra Dipartimento di Fisica e Astronomia Università di Catania and INFN.

High-p T Particles and RHIC Paradigm of Jet Quenching Ahmed M. Hamed NN2012 The 11 th International Conference on Nucleus-Nucleus Collisions 1.

Collaborators: Bugra Borasoy – Bonn Univ. Thomas Schaefer – North Carolina State U. University of Kentucky CCS Seminar, March 2005 Neutron Matter on the.

The study on the early system just after Heavy Ion Collision Ghi R. Shin (with B. Mueller) Andong National University J.Phys G. 29, 2485/JKPS 43, 473 Korean-EU.

Hua Zheng a and Aldo Bonasera a,b a)Cyclotron Institute, Texas A&M University b)LNS-INFN, Catania-Italy Density and Temperature of Fermions.

Nuclear Enthalpies or Nucleon Properties inside Compressed Nuclear Matter Jacek Rozynek ‘‘Is it possible to maintain my volume constant when the pressure.

Nuclear Matter Density Dependence of Nucleon Radius and Mass and Quark Condensates in the GCM of QCD Yu-xin Liu Department of Physics, Peking University.

Structure of quantum chromodynamics, glueballs and nucleon resonances H.P. Morsch (in collaboration with P. Zupranski) Warsaw,

PHENIX Results from the RHIC Beam Energy Scan Brett Fadem for the PHENIX Collaboration Winter Workshop on Nuclear Dynamics 2016.

Department of Physics, Sungkyunkwan University C. Y. Ryu, C. H. Hyun, and S. W. Hong Application of the Quark-meson coupling model to dense nuclear matter.

高密度クォーク物質におけるカイラル凝縮とカラー超伝導の競合 M. Kitazawa,T. Koide,Y. Nemoto and T.K. Prog. of Theor. Phys., 108, 929(2002) 国広悌二 ( 京大基研）東大特別講義 2005 年 12 月 5-7 日 Ref.

Strange hadrons and resonances at LHC energies with the ALICE detector INPC 2013 Firenze, Italy 2 -7 June 2013 A. Badalà (INFN Sezione di Catania) for.

Duke University 野中千穂 Hadron production in heavy ion collision: Fragmentation and recombination in Collaboration with R. J. Fries (Duke), B. Muller (Duke),

Relativistic EOS for Supernova Simulations

Electric Dipole Response, Neutron Skin, and Symmetry Energy

Short-Range Correlations in Asymmetric Nuclei

Nuclear Effects in the Proton-Deuteron Drell-Yan Reaction.

Neutron Stars Aree Witoelar.

Aspects of the QCD phase diagram

Grigory Nigmatkulov National Research Nuclear University MEPhI

Fragmentation or Recombination at High pT?

Variational Calculation for the Equation of State

A possible approach to the CEP location

Chemical Equilibrium Mass transfer takes place from higher chemical potential to lower chemical potential. If the chemical potential of reactants are.

Effects of the φ-meson on the hyperon production in the hyperon star

Presentation transcript:

Nucleon PDF inside Compressed Nuclear Matter Jacek Rozynek NCBJ Warsaw ‘‘Is it possible to maintain my volume constant when the pressure increases?” - an nucleon when entering the compressed medium. J. Phys. G: Nucl. Part. Phys. 42 (2015) Nuclear Entalpies, ; Pressure Corrections to the Equation of State in the Nuclear Mean Field, , Acta Phys. Pol. B Proc. Suppl. Vol. 5 No 2 (2012) 375 Valparaiso QNP2015

Introduction The aim is to check two approximations of The nuclear Relativistic Mean Field Model 1. constant nucleon mass 2. no nucleon volumes i compressed NM Possible applications in HI colisions and inside neutron stars. Valparaiso QNP2015

Finite volume effect in compressed medium Nucleon inside saturated NM Compressed inside Neutron Star or in H I collision Nucleon pressure

Two Scenarios for NN repulsion with qq attraction Constant Volume = Constant Enthalpy Constant Mass = Increasing Enthalpy 1/R Valparaiso QNP2015 ΩAΩA ΩNΩN ΩNΩN

Two Scenarios affecting nuclear compressibility K A -1 Constant Volume = Constant Enthalpy Constant Mass = Increasing Enthalpy 1/R Valparaiso QNP2015

Definitions Enthalpy is a measure of the total energy of a thermodynamic system. It includes the system's internal energy and thermodynamic potential (a state function), as well as its volume Ω and pressure p H (the energy required to "make room for it" by displacing its environment, which is an extensive quantity). H A = E A + p H Ω A Nuclear Enthalpy (1) H N = M pr + p H Ω N Nucleon Enthalpy (2) Specific Enthalpies (3) h A (      p H  h N (  ) = H N /M pr = 1+ p H /(  cp M pr  Valparaiso QNP2015

Enthalpy vs Hugenholz - van Hove relation with chemical potential (1a) Valparaiso QNP2015 Also valid for constant nucleon volumes !!

Nuclear convolution model f N (y) Light cone variables in the rest frame x=k + /p N + y=p N + /P A

RMF and Momentum Sum Rule Frankfurt, Strikman Phys. Reports 160 (1988) (4) Valparaiso QNP2015 (Jaffe)

Finally with a good normalization of S N we have: and Momentum Sum Rule Flux Factor Fermi Energy Enthalpy/A B - =B 0 -B 3 B-B- q=0 kk No NN pairs baryon current P 0 A =E A =A  A Valparaiso QNP2015

Bag Model in Compress Medium p H =0 (7) Valparaiso QNP2015

Nucleon compressibilty and two scenarios Constant Nucleon Mass Constant Nuclear Radius Semi-experimental Value sum rules K N -1 =>M E x 2 (Morsch, Julich, PRL 1995) From 7Gev/c (α,p) scattering in P 11 region in SATURN

K -1 =235MeVfm -3 Nuclear compressibility for different constant nucleon radii in compressed NM Nucleon Mass for different nucleon radii in compressed NM Our version of Hugenholz-Van Hove relation for finite nucleons in NM Valparaiso QNP2015

Nucleon radius in compressed NM for a constant nucleon mass Bag constant in function of nuclear pressure Valparaiso QNP2015

RMF Equation of State for const Enthalpy scenario B (8) (9) Valparaiso QNP2015

Equation of state - different models Valparaiso QNP2015

Results Valparaiso QNP2015 SASA SBSB

Two possible scenario of phase transition A - constant nucleon radius, B - constant nucleon mass Energy alignment  cr  (  cr ) =  cp M(  cr ) R[fm]=0.8 -> rd International Conference on New Fronties in`Physics Valparaiso QNP2015

A model for parton distribution σ =1/(2R) k + = xp + Kinematical conditions for Monte Carlo technique Primodial quark transverse momentum distribution Line cone variables in the nucleon rest frame COMPRESSED Nuclear Case p + rest = H N (R)

Nuclear Models - equilibrium JR G.Wilk PLB 473 (2000) Only 1% of nuclear pions Phys. Rev. C71 (2005) Shifting pion mass f N (y)

Toy Model (Edin and Ingelman) (Neglecting transverse quark momenta) In our case d h m h => R*H N (R) is const. But the x=k + /H N (R(ρ)) depends on nucleon density where

Finite Nucleon Volumes - Conclusions A. Constant nucleon mass requires increasing enthalpy STIFFER EOS Shift in Bjorken X B. Constant nucleon volume gives the constant enthalpy with decreasing nucleon mass, lower compressibility SOFTER EOS A&B. In both cases the same width of parton distribution because R*H N (R) const. Valparaiso QNP2015

The toy model for phase transition Valparaiso QNP2015

PRC 74 our model Valparaiso QNP2015