Hiroshi Toki focuses on Atomic physics, Nuclear physics, Mean field theory, Nuclear matter and Particle physics. As a part of the same scientific family, Hiroshi Toki mostly works in the field of Atomic physics, focusing on Nucleus and, on occasion, Valence, Neutron density, Nuclear cross section and Bound state. Nuclear physics and Resonance are frequently intertwined in his study.
His Mean field theory study combines topics in areas such as Neutron, Isotope and Ground state. His research in Nuclear matter intersects with topics in Momentum transfer, Quantum electrodynamics, Equation of state and Nonlinear system. His work carried out in the field of Particle physics brings together such families of science as Scattering amplitude and Renormalization.
His primary areas of study are Particle physics, Nuclear physics, Atomic physics, Quantum electrodynamics and Nucleon. His Nuclear physics study incorporates themes from Mean field theory and Pairing. His studies deal with areas such as Parity, Binding energy and Ground state as well as Mean field theory.
His study in Atomic physics is interdisciplinary in nature, drawing from both Spectral line, Excitation and Nucleus. His Quantum electrodynamics research is multidisciplinary, incorporating perspectives in Quantum mechanics, Wave function and Mathematical physics. He combines subjects such as Hartree–Fock method, Supernova and Equation of state with his study of Nuclear matter.
His primary areas of investigation include Tensor, Molecular dynamics, Quantum mechanics, Neutron and Nucleon. His studies in Tensor integrate themes in fields like Excited state, Light nucleus, Atomic physics, Molecular physics and Space. His Neutron study combines topics from a wide range of disciplines, such as Range, Nuclear structure, Proton and Nuclear matter.
His work in Nuclear matter addresses subjects such as Pion, which are connected to disciplines such as Coupling constant. His Nucleon research incorporates elements of Momentum, Periodic boundary conditions and Mathematical physics. He has researched Nuclear physics in several fields, including Stars and Neutron star.
His main research concerns Tensor, Molecular dynamics, Nucleon, Quantum mechanics and Nuclear physics. His Tensor research is multidisciplinary, relying on both Space, Atomic physics and Nuclear theory. His work deals with themes such as Kinetic energy and Cluster, which intersect with Atomic physics.
His Nuclear theory study which covers Nuclear matter that intersects with Neutron. As part of one scientific family, Hiroshi Toki deals mainly with the area of Nucleon, narrowing it down to issues related to the Momentum, and often Periodic boundary conditions. His work focuses on many connections between Nuclear physics and other disciplines, such as Particle physics, that overlap with his field of interest in Lambda.
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Relativistic mean-field theory for unstable nuclei with non-linear σ and ω terms
Y. Sugahara;H. Toki.
Nuclear Physics (1994)
Relativistic equation of state of nuclear matter for supernova and neutron star
H. Shen;H. Shen;H. Toki;K. Oyamatsu;K. Sumiyoshi.
Nuclear Physics (1998)
Relativistic continuum Hartree Bogoliubov theory for ground-state properties of exotic nuclei
J. Meng;J. Meng;H. Toki;S.G. Zhou;S.Q. Zhang.
Progress in Particle and Nuclear Physics (2006)
Pionic modes of excitation in nuclei
E. Oset;H. Toki;W. Weise.
Physics Reports (1982)
Revelation of thick neutron skins in nuclei
I. Tanihata;D. Hirata;T. Kobayashi;S. Shimoura.
Physics Letters B (1992)
Relativistic equation of state of nuclear matter for supernova explosion
Hong Shen;Hong Shen;Hiroshi Toki;Kazuhiro Oyamatsu;Kohsuke Sumiyoshi.
Progress of Theoretical Physics (1998)
Postbounce evolution of core-collapse supernovae: Long-term effects of equation of state
K. Sumiyoshi;S. Yamada;H. Suzuki;H. Shen.
arXiv: Astrophysics (2005)
An effective interaction for inelastic scattering derived from the Paris potential
N. Anantaraman;H. Toki;G.F. Bertsch.
Nuclear Physics (1983)
EXPERIMENTAL EVIDENCE FOR A LIQUID - GAS PHASE TRANSITION IN NUCLEAR SYSTEMS
A. D. Panagiotou;M. W. Curtin;H. Toki;D. K. Scott.
Physical Review Letters (1984)
Color confinement, quark pair creation and dynamical chiral-symmetry breaking in the dual Ginzburg-Landau theory
H. Suganuma;S. Sasaki;H. Toki.
Nuclear Physics (1995)
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