Low Energy Nuclear Theory!
National Nuclear Physics Summer School 2019!
Low Energy Nuclear Theory!
KD Launey!
LA Light Source
Louisiana State University!
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Low Energy Nuclear Theory. National Nuclear Physics Summer School 2019. Lecture 1. Modeling nuclei: structure …and reactions. Numerous successful approaches ...
Typology: Exercises
2022/2023
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Low Energy Nuclear Theory
KD Launey
LA Light Source
Louisiana State University
Low Energy Nuclear Theory
KD Launey
LA Light Source
Louisiana State University
LA Light Source @ LSU
Fantastic 4
… nuclei… elements… stars…
q u a r k s & g l u o n s
U N I V E R S E
Condensed
Matter
Nuclear
p r o t o n s n e u t r o n s
From Nucleons to Stars
… nuclei… elements… stars…
q u a r k s & g l u o n s
U N I V E R S E
Condensed
Matter
Nuclear
p r o t o n s n e u t r o n s
- How did visible matter come into being and how does it evolve?
2.How does subatomic matter organize itself and what phenomena emerge?
3.Are the fundamental interactions that are basic to the structure of
matter fully understood?
- What are the origins of heavy elements?
The Big Science Questions
… nuclei… elements… stars…
q u a r k s & g l u o n s
U N I V E R S E
Condensed
Matter
Nuclear
p r o t o n s n e u t r o n s
FRIB (Facility for Rare Isotope Beams)
Ab initio Theory Density Functional Theory
Astrophysics: the origin of the elements
NIF (National Ignition Facility) at Lawrence Livermore National Lab T2K; DUNE
Advanced
LIGO
Neutrino physics;
fundamental symmetries
Nuclei: fuel of the Cosmos and ideal labs!
Applied energy Neutrino Detectors
(^12) C, 16 O, 40 Ar
Neutrinoless ββ decay
FRIB (Facility for Rare Isotope Beams)
Advanced
LIGO
… nuclei… elements… stars…
q u a r k s & g l u o n s
U N I V E R S E
Condensed
Matter
Nuclear
p r o t o n s n e u t r o n s
Ab initio Theory Density Functional Theory
Astrophysics: the origin of the elements
NIF (National Ignition Facility) at Lawrence Livermore National Lab T2K; DUNE
Neutrino physics;
fundamental symmetries
Why Ab initio?
Applied energy Neutrino Detectors
(^12) C, 16 O, 40 Ar
Neutrinoless ββ decay
✓Explains ✓Predicts
Measured masses
Mass difference, MeV
Rb
D. Lunney, CSNSM (2004)
Unstable nuclei: need reliable
prediction (mass models diverge)
Nucleus – relevant scales
baryon chemical potential =
measure of net baryon density
baryon = made of 3 quarks
(protons, neutrons, …)
mesons = made of quark-antiquark
(pions, …)
hadrons
Nucleus – relevant scales
Mass of nucleon
(proton or neutron)
~1 GeV = 10 3 MeV
Separation energy
per particle
6-8 MeV
Nucleus – relevant scales
Mass of nucleon
(proton or neutron)
~1 GeV = 10 3 MeV
Separation energy
per particle
6-8 MeV
dof= nucleons + mesons
Mass of pion
~140 MeV
low-energy
nuclear physics
Radioactive beam facilities
(FRIB)
Intermediate energy
High energy
a few GeV
GeV/TeV
Size ~0.8 fm
Nucleus – relevant scales
Mass of nucleon
(proton or neutron)
~1 GeV = 10 3 MeV
Separation energy
per particle
6-8 MeV
dof= nucleons + mesons
Mass of pion
~140 MeV
Intermediate energy
High energy
a few GeV
GeV/TeV
Size ~0.8 fm
Many
surprises:
nuclear sizes!
Various dof
² Collective
² Clusters
² Halo
Modeling the nucleus … The challenges
Interaction
between particles
States
NN, 3N, ...
E.g., 6 particles in 200 states:
8x10 10 ways !!!
E.g., 2 particles in 4 states
|1100> |0011>
|1010> |0101>
|1001> |0110>
Model space
available to nucleus
All possible ways:
20 particles in 80 states
HUGE!
Reproduces NN scattering
(these are free nucleons,
not in nuclear medium;
I will refer to this force
as “bare”)
In addition, there might
be 3N, 4N, …
Modeling the nucleus … The ingredients
Specified by
basis,
model space (size & resolution)
Many-body Approach
Nuclear properties:
structure & reactions
Nuclear force
L (^) eff
1/Λeff
“size”
“resolution”
Resolving high-
momentum
physics
Important for
wave function tail,
large shapes/clusters,
asymptotics, etc.
Two-body problem
v A=2: pp (
2 He), pn ( 2 H), nn (?)
v Non-relativistic quantum mechanics: H = T rel + V( r,r’ )
r Center of mass (CM)
Relative (intrinsic)
Position:
Momentum:
T =
2M M/2 (^) Reduced mass
Global motion of a free nucleus is described by a
plane wave with momentum P
(irrelevant to the intrinsic nuclear dynamics)
Entem & Machleidt
v Realistic interactions:
NN reproduce phase shifts to high precision
Chiral Potentials
Quark/gluon dynamics
(Quantum
chromodynamics, QCD)
Degrees of freedom Symmetry
High energy What is most important for a
theory? The symmetries and
not the degrees of freedom
The usual (Lorentz
covariance, parity, etc.)+
L = − (^) Chiral symmetry
1
4
G ∝ν
a Ga
∝ν
- q (^) L i γ∝ D
∝ q (^) L + q (^) R i γ∝ D
∝ q (^) R − q M q
Nucleon/pion dynamics
(Effective field theory)
Low energy