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Yoshio Nishina 1890-1951

Hideki Yukawa 1907-1981. Sin-itiro Tomonaga 1906-1979. Yoshio Nishina 1890-1951. H. Nagaoka , 1865-1950. Yukawa, Kikuchi and Bohr. Yukawa, Tomonaga, Sakata. Search for hadron internal symmetries Flavor symmetry SU(2) for (p,n), ( π ± , π 0 ) (Kemmer)

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Yoshio Nishina 1890-1951

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  1. Hideki Yukawa 1907-1981 Sin-itiro Tomonaga 1906-1979 Yoshio Nishina 1890-1951

  2. H. Nagaoka, 1865-1950 Yukawa, Kikuchi and Bohr

  3. Yukawa, Tomonaga, Sakata

  4. Search for hadron internal symmetries Flavor symmetry SU(2) for (p,n), (π±,π0) (Kemmer) SU(3) octet hadrons (Gell-Mann, Neéman) Vector meson dominance (Sakurai, 1960) ρ(770),I=1; ω(780),I=0 Chiral symmetry (handedness) V - A weak interaction symmetry broken by fermion mass almost conserved axial vector current (PCAC, σ model)

  5. The collective modes Langmuir plasma ωP2 = e²ρ/m Debye screening e-μr/r, μ = ωP/vT Bohm and Pines (1951-53) longitudinal and transverse collective modes London theory of superconductivity j=(1/Λ)A, 1/Λ= ωP

  6. Tomonaga effective theory for 1-D fermionic systems Simple transcription H =∫ψ†p²/(2m)ψ +1/2∫∫′(ψ†ψ)V(ψ† ψ, ψ† →ρ½ exp(±iθ), [θ,ρ]= ih/2π  I ω(k)² = (k²/m)(ρ₀V(k) + k²/(4m) V = e²/r : ω² = e²ρ₀/m + k²/(4m)

  7. J. Bardeen, 1908-1991

  8. BCS theory (1957) Cooper pairing and gap formation around the Fermi surface Bogoliubov-Valatin quasiparticles Ψ= αψ↑+βψ↓† HBV = Ψ†(τ₃ε+τ₁Δ)Ψ, Ψ=(ψ↑,ψ↓†) Collective modes π ~ Ψ†τ₂Ψ, m=0 (NG) σ ~ Ψ†τ₁Ψ,m=2Δ (Higgs) London relation (“field-current identity”) J = A/Λ Conserved current J =Ψ†(p -τ₃eA)Ψ -∇π ∂ρ/∂t +∇⋅J=0

  9. Chiral problem and nucleon mass generation Chiral invariants SSB of chiral symmetry by mass HN = Ψ†(ρ₁σ⋅p+ ρ₃M + gρ₂π)Ψ Chiral (axial) current jAμ=Ψ†(ρ₁, σ)Ψ, ∂ ⋅j A= -2MΨ†ρ₂Ψ , JAμ= jAμ- f ∂μπ f = 2M/g (Goldberger-Treiman) ∂⋅J = fmπ² PCAC Collective modes (mesons) π mass ~ 0 σ mass ~ 2M

  10. General mass relations NG fermion “Higgs” 0 1 2 BCS 0 1 2 hadrons 0 1 2 3He-B ~ σ⋅p 0 1 2 J=0 ~ σ×p 0 1 2 J=1 ~ σipk2(2/5)1/2 1 2(3/5)1/2 J=2 m₁² + m3² = 4m2² Quarks and Higgs mass relations?

  11. Nontrivial problems of SSB (Jona-Lasinio, 2010) SSB in non-equilibrium processes Superfluid He flow : Bose condensation of NG phonon modes 1-D phase transition not possible, but 1-D highway traffic model (Popkov et al 2008) >------------ ↘ _________ ↗ -------------> <------------ ↗ ↘ -------------< Role of SSB in cosmology?

  12. Brief history of particle physics since the 1930s Neutron, positron Cyclotron (Lawrence) Beta decay theory Meson theory (Yukawa) Muon (second lepton) *Pion (first meson) QED and renormalization *Non-Abelian gauge fields *Various hadrons (ρ,ω, etc.) and flavor symmetry *Parity violation with V - A weak interaction *Chiral symmetry *Spontaneous symmetry breaking and mass generation *Quark model Regge trajectories of hadrons *Electroweak unification Quark color and QCD The standard model SU(3)xSU(2)xU(1) gauge fields, 3 generations of quarks and leptons

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