Post on 21-Jan-2016
DYNAMICAL PION COLLAPSE &
THE COHERENCE OF NEUTRINO BEAMS
Benjamin J. P. Jones, MIT
Talk at Pheno2015, Pittsburgh, PA
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Here is a neutrino oscillation according to the “standard” plane-wave picture, in mass and flavor spaces:
PLANE-WAVE PICTURE
Source Osc MaxRe(ψ)
P(f)
m1m2
μ
e
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PROPAGATION WITH WAVEPACKETS
We know that really its not a plane wave.
Wave-packets can separate. After that, system is incoherent (no L or E depedence)
Re(ψ)
P(f)
Source Osc Max
Kicks in sooner with big Δm2 or small
packet width
m1m2
μ
e
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IS THIS IMPORTANT?
Could this affect standard or sterile neutrino phenomenology?
To find out, We need to know the speed of separation (easy),
and the wave-packet width (not so easy)
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Important progress was made by Beuthe, Akmedov +Smirnov :
They calculated neutrino state emerging from a pion of a specified width, alongside a specified detected muon
EXTERNAL WAVE-PACKET PICTURE
π Decay Lagrangia
n μ
ν
Specified final state
?Input
Input
Output
Beuthe arxiv:0109119 Akhmedov + Smirnov arxiv:0905.1903
But … now two unknown states, rather than one!
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The usual approach:
Wave our hands and make something up!
The width of the incoming pion wave-packet “must” be:
1. The inverse of its mass width
2. The mean-free path between collisions
3. Something to do with its form factor / physical size
4. The length of the decay pipe
5. Very small / big / … something?
It can be calculated without hand-waving / arbitrary scale assumptions, and it turns out that none of the above are the correct answer:
Phys.Rev. D91 (2015) 5, 053002 [B.J.P.J.]
WIDTH OF THE INCOMING PION?
πInput
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Start with some pion density matrix:
FIRST, TRANSLATE INTO THE DENSITY MATRIX PICTURE.
And let it decay:
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REDUCING, TRACING, MEASURING….
Density matrix for entangled muon-neutrino system emerging from general pion state ρπ
Tracing out the muon and apply a flavor measurement operator at baseline L:
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To get an idea of the phenomenology, substitute a representative pion density
matrix with Gaussian on and off diagonal position widths:
THE OSCILLATION PROBABILITY
Standard oscillation Classical coherencecondition
Quantum coherencecondition
Know location of source to within 1
osc length
Need WP’s not toseparate
x1
x 2
quantum clas
sica
l
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What is the coherent pion width?
LOCALIZATION BY SCATTERING
x
ψ
E1
E2
E3
E4
With environmental entanglement the pion has
both a total width and a coherent width
E0
π
Repeated bombardment of scatterers encodes information about the pion into the environment.
Coherence of neutrino emission from spatial parts of the WF is then suppressed by environmental entanglements.
Basic principle of environmentally induced decoherence (used in quantum computing, interferometry, etc)
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Under some loose assumptions, we can describe what happens to the pion reduced density matrix without
considering the full system DM
OPEN QUANTUM SYSTEMS
E0
π
FT of mom transfer prob dist
quantumcl
assica
l
OPEN QUANTUM SYSTEMS
quantumcl
assica
l
T=0T=1T=2
Between scatters the state evolves according to the free Schrodinger equation
This leads to dispersion (broadening) of both coherent and incoherent widths
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COHERENCE LENGTHS
Tegmark, arxiv:9310032
Competition of unitary evolution and collapse define a stable coherent width:
To calculate this width for a relativistic pion, we need:1) Scattering momentum transfer probability
distribution + rate2) Method of calculating convergent width in a
relativistic system
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MOMENTUM TRANSFERS
Derived from photoionization cross section, in a somewhat complicated way
We need photoionization spectrum of beam-pipe gas as input:
Semi-classical model – consider energy losses in a continuum with some complex refractive index and re-interpret in terms of photon exchanges with electrons
Photoioniziation input
Measured drift chamber
fluctuations
Corrected Landau
PAImodel
Allison and Cobb,Ann.Rev.Nucl.Part.Sci 1980. 30:253-98
PAI Model:
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PAI SANITY CHECK
My PAI model implementati
on
Standard plot of energy losses from the PDG
THE DECOHERENCE FUNCTION
Collapse this
way
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SIMULATING DYNAMICAL COLLAPSE
Time
No longer fits on grid, simulation halts
Start with very
narrow pure state
density matrix evolve / scatter / evolve / scatter / evolve /
scatter…
These ingredients are used to construct a dynamical wave-function collapse MC simulation of the pion evolution:
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Dispersion winning
Collapse winning
Eq
uilib
riu
m
SIMULATING DYNAMICAL COLLAPSE
(note timescale for collapse)
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Map out collapsed widths as a function of incoming pion momentum
And substitute into fancy oscillation formula to find coherence loss distance
COLLAPSED WIDTHS
Standard oscillation Classical coherencecondition
Quantum coherencecondition
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DRUMROLL PLEASE!
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There will be no coherence loss effects for active neutrinos from accelerator neutrino beams anywhere on Earth
There may be coherence loss effects for heavy sterile neutrinos, but not observable in SBN experiments
Previous analyses and sensitivities are meaningful (phew!)
This work demonstrates a rigorous prediction of when neutrinos become incoherent, using a new approach: the open quantum system picture of
neutrino beams
There are other neutrino sources where the effects are still unknown : reactors, decay-at-rest, etc. Those sound like fun to think about next!
CONCLUSION
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BACKUPS
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Re(ψ)
P(f)
PROPAGATION WITH WAVEPACKETS
Phase velocity is not affected – so neither is oscillation length
No process can make a neutrino of perfectly defined momentum.
Source makes a wave-packet with some momentum and some position width
m1m2
Source Osc Max
μ
e
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COHERENCE LENGTHS
Calculated analytically by solving a master equation:Tegmark, arxiv:9310032
Competition of unitary evolution and collapse to define a stable width:
YOUNGS TWO-SLIT EXPERIMENT
A
B
scre
en
slit
s
source
Interference pattern:
YOUNGS TWO-SLIT EXPERIMENT
A
B
scre
en
slit
s
source
What if we add an environment?
E0
E0
YOUNGS TWO-SLIT EXPERIMENT
A
B
scre
en
slit
s
source
Switch on the coupling.
The particle becomes entangled with the environment via its interactions
The interference pattern now depends on how much overlap there is between EA, EB
EA
EB
?
YOUNGS TWO-SLIT EXPERIMENT
A
B
scre
en
slit
s
source
Extreme cases :
EA
EB
Fully quantum-mechanical-looking particles
YOUNGS TWO-SLIT EXPERIMENT
A
B
scre
en
slit
s
source
Extreme cases :
EA
EB
Fully classical-looking particles
Diverging entanglements with the environment make quantum-looking systems into classical-looking ones
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SEEING DECOHERENCE IN PRACTICE
e.g. Talbot Lau interferometry with C70 fullerenes
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Environmental gasses are bled into the vacuum chamber. These cause scattering interactions.
Entanglements generated with the environment encode “which way” information and suppress coherent superpositions.
3*10-8 mbar 5*10-7 mbar ArPrediction from decoherence theory
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Now consider a superposition of two particle position states, talking to an environment, which is “measuring”
them with some resolution.
POSITION STATES OF A PARTICLE
PA
PB
E0Time
PA
PB
EA
EB
PA
PB
E0 TimePA
PB
EA~EB Narrowly
separated
Widely separated
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The particle (in superposition of positions) emits a neutrino. Will the neutrino state from each emitter add coherently or
incoherently?
POSITION STATES OF A PARTICLE
PA
PB
E0Time
PA
PB
EA
EB
PA
PB
E0 TimePA
PB
EA~EB Narrowly
separated
Widely separated
ν ν
ν ν
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POSITION STATES OF A PARTICLE
PA
PB
E0Time
PA
PB
EA
EB
PA
PB
E0 TimePA
PB
EA~EB Narrowly
separated
Widely separated
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THE ROLE OF THE MUON
Interaction
Detector
Freedom!
Un
itary
evo
luti
on
mean
s th
at
the n
eu
trin
o
doesn
’t c
are
!
μ
μ
μ
ν
ν
ν
See also:Glashow 0810.4602Kayser1110.3047
The existence of the muon is very important.
It is a part of the final state. Only neutrino trajectories which “go with the same muon” can
interfere coherently.
Once the muon leaves the interaction point, its role in the process is complete.
Its subsequent interactions / measurement cannot affect neutrino oscillation phenomenology (see: causality)
This is a consequence of unitarily, and an exact analogue of the EPR thought experiment.
Appendix 1 of the paper gives a very general proof
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KINEMATICS
Oscillations require i≠j terms to be non-zero.
Can only happen if the pion density matrix is coherently wide enough (δ):
δ
pμ pμ
pν,mipν,mj
pπ pπ+2δij
How should we understand δ?
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NOW WITH NEUTRINO MASSES:
Build total density matrix for muon-neutrino system emerging from general pion state ρπ
Trace out the muon to get neutrino reduced DM:
Use it for oscillation physics:
Section 2 of paper
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CHANGING DECAY ENVIRONMENT