APCTP Focus Program in Nuclear Physics 2021 Part I: Hadron properties in a nuclear medium from the quark and gluon degrees of freedom
Online (ZOOM)
APCTP Focus Program in Nuclear Physics 2021 Part I: Hadron properties in a nuclear medium from the quark and gluon degrees of freedom
Online Meeting (ZOOM)
14 - 16 July, 2021
9 AM - 12:30 PM, Asia/Seoul and Asia/Tokyo Timezone,
10 AM - 1:30 PM, Australia/Adelaide Timezone,
9 PM - 00:30 AM (-1 day), America/Sao_Paulo Timezone
Supported by APCTP and CHEP@KNU
https://indico.knu.ac.kr/e/APCTP2021-NP1
ZOOM Registration Link: https://zoom.us/meeting/register/tJAsf--hrzsjH9L3fUa-ysZaDlnKT47RXZ2O
Quantum Chromodynamics (QCD) is the theory of strong interaction for quarks and gluons, namely, describing the dynamics of strongly interacting particles, hadrons and atomic nuclei. QCD explains the origin of dynamically generated masses of hadrons, where, the dynamical masses explain more than 90% of the physical masses of proton, neutron, and baryons that we experimentally observe. Thus, the dynamical mass gives most of the mass and energy of the ordinary matter around us, or the “visible universe”. (Yet, we admit that the universe contains only 5% of ordinary matter and/or energy, 27% of dark matter, and 68% of an unknown “dark energy”.)
Although the present program focuses on this 5% portion of the total energy in the whole universe, the normal matter around us (protons, neutrons, hadrons) is already very interesting, and shows com- plicated phenomena in free space. However, surprisingly even more, the hadrons which compose the normal matter or most of the visible universe, reveal further unexpected, very exciting and rich feature under the environments such as high density and/or temperature. The properties of hadrons in such environments are far remote from our present understanding in terms of the original theory of QCD. Namely, hadrons feel complicated interactions from the surrounding environment, medium, where the interactions should arise from QCD, but very difficult to explain by it. For example, systems under such environments are, cores of heavy nuclei, neutron star and compact star cores, and dense and/or high temperature matter produced in heavy-ion collisions. These are the topics to be discussed through this Focus Program.
Supported by
Asia Pacific Center for Theoretical Physics
Center for High Energy Physics, Kyungpook National University
NRF through Department of Physics, Kyungpook National University
Aaron Park
Ahmad Jafar Arifi
Anthony Thomas
Arthur Pasqualotto
Atsushi Hosaka
AYSE KIZILERSU
Bruno El-Bennich
Byung-Geel Yu
Chang-Hwan Lee
Chueng-Ryong Ji
Daiki Suenaga
Daisuke JIDO
Denny Lane Sombillo
George Yabusaki
Gilberto Ramalho
Guilherme Zeminiani
Gustavo Vaccani
Hana Gil
Ho-Meoyng Choi
Hungchong Kim
Hyeon-Dong Son
Hyon-Suk Jo
hyungjoo kim
Izzie shurvinton
Javier COBOS MARTINEZ
Jekyung Jeong
João Pacheco de Melo
Julio Cesar Chirichella Felicioni de Souza
june-young kim
Jurandi Leão
Kazuo Tsushima
Kyungseon Joo
Lata Thakur
Makoto Oka
Minsu Kwon
Myeong-Hwan Mun
Myungkuk Kim
Parada Tobel Paraduan Hutauruk
Philipp Gubler
Ricardo Farias
Roberto Correa da Silveira
Rômulo Moita
Sakinah -
Sangyeong Son
Satoru Hirenzaki
Seung-il Nam
Soonchul Choi
Su Houng Lee
Talita Souza Siqueira
Theo Motta
Wasif Husain
Wayne de Paula
Wooyoung KIM
XUANGONG WANG
Yamato Suda
Yeunhwan Lim
Yongseok Oh
Yongwoo Choi
Young-Min Kim
Yutaro Iizawa
