0 physics of neutrinos from boris kayser, fermilab
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Physics of NeutrinosPhysics of Neutrinos
From Boris Kayser, Fermilab
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The last seven years
Compelling evidence that neutrinos have mass and mix
Open questions about the neutrino world
Study of neutrino mixing matrix
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Neutrinos are created in a variety of physical processes.In nature or the laboratory, a neutrino is created together with a charged lepton. The neutrino and charged lepton always have the same flavor.
oror
Not
e
e
Source
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When a neutrino collides with an atom in a neutrino detector, it creates a charged lepton.The charged lepton always has the same flavor as the neutrino.
or or
Not
e
e
Detectore
e, , are weak interaction states
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e
e
Detectore
e
Source
The flavors match.
Creation and Detection of a Neutrino
Short Journey
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The Discovery of Flavor Change
The last 7 years have yielded compelling evidence that, given enough time, a neutrino can change from
one flavor into another.
Detector
SourceLong Journey
This is surprising behavior.
Once an electron, always an electron.
But once a e, not always a e.
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How We Know Neutrinos Change Flavor
In the core of the sun
Nuclear Reactions
Solar neutrinos are all born as e , not or .
e
e
— Solar Neutrinos —
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SNO detects solar neutrinos in several different ways.
One way counts
Number (e) .
Another counts
Number (e) + Number () + Number () .
SNO finds
Number (e) Number (e) + Number () + Number ()
= 1/3 .
CC
NC
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All the solar neutrinos are born as e .
Neutrinos change flavor.Neutrinos change flavor.
But 2/3 of them morph into or
before they reach earth.
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— Atmospheric Neutrinos —
Cosmic rays come from all directions at the same rate.
So atmospheric neutrinos are produced all around the earth at the same rate.
But Number ( Up) / Number ( Down) = 1/2.
Detector
Cosmic ray
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Half the that travel to the detector from the far side of the earth disappear en route.
The detailed data show that the disappearance is due to —
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Evidence For Flavor Change
Neutrinos
Solar
Atmospheric
Reactor
Accelerator
Evidence of Flavor Change
Compelling
Compelling
Compelling
Strong
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Neutrino Flavor Change Implies Neutrino Mass
The neutrinos we study pass through matter between their source and our detector.
Can’t their interactions with the matter change their flavor?
In practice, no.
We have confirmed that the interactions between neutrinos and matter are very well described by the Standard Model of elementary particle physics.
Standard Model neutrino interactions do not change neutrino flavor.
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The Physics of Neutrino Flavor Change
If particles like the electron never morph into something else, how can a morph into a ?
Answer: A is not a particle to begin with.
There are neutrino particles:Neutrino Particle Mass
1
2
3
m1
m2
m3
(And maybe more.)
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e, , and are different MIXTURES of 1, 2, and 3.
In each of—
e
e
the emitted neutrino is actually a 1, 2, or 3.
is:
Probability
17 %
34 %
49 %
maybe 1
maybe 2
maybe
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The world of the subatomic particles is governed byQUANTUM MECHANICS.
An object can be maybe here and maybe there. It can be maybe this and maybe that.
It can be maybe a 1, maybe a 2, and maybe a 3.
Quantum mechanics involves uncertainty at its core.
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Long Journey
Voyage of a Neutrino
Original 1, 2, 3
mixture
New, different 1, 2, 3
mixture
1, 2, 3 travel differently because they have different
masses.
The mixture of 1, 2, 3 has turned into the mixture. Neutrino flavor change is a quintessentially quantum
mechanical phenomenon.
It occurs over VERY LARGE distances.
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The quantum mechanics of flavor change results in an oscillation back and forth between the initial flavor and the new one.
Thus, flavor change is called —
NEUTRINO OSCILLATIONNEUTRINO OSCILLATION
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What WeWhat We Have Learned Have Learned
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The Neutrino Mass Spectrum
There are at least 3 neutrino particles: 1, 2, 3.
Neutrino oscillation results have revealed the differences between the squares of their masses.
The spectrum of squared masses looks like —
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(Mass)2
1
2
3
or
1
23
}m2sol
m2atm
}m2sol
m2atm
m2sol = m2
atm / 30
m2atm = (Electron mass / 10,000,000)2
Not above (Electron mass / 1,000,000)2. {From Cosmology}
m2sol = 7.9 x 10–5 eV2, m2
atm = 2.4 x 10–3 eV2
Normal Inverted
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When one of the neutrino particles (1, 2, or 3)
interacts in a detector and makes a charged lepton, this charged lepton could be an e, a , or a .
It’s that quantum-mechanical uncertainty again!
But, for each neutrino particle, we know the probability that the charged lepton it produces will be of any
particular flavor.
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e
e
e 1
2
3
The Probabilities of Making e, , and
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The Mixing Matrix
€
U =
1 0 0
0 c23 s23
0 −s23 c23
⎡
⎣
⎢ ⎢ ⎢
⎤
⎦
⎥ ⎥ ⎥×
c13 0 s13e−iδ
0 1 0
−s13eiδ 0 c13
⎡
⎣
⎢ ⎢ ⎢
⎤
⎦
⎥ ⎥ ⎥×
c12 s12 0
−s12 c12 0
0 0 1
⎡
⎣
⎢ ⎢ ⎢
⎤
⎦
⎥ ⎥ ⎥
×
eiα1 /2 0 0
0 eiα 2 /2 0
0 0 1
⎡
⎣
⎢ ⎢ ⎢
⎤
⎦
⎥ ⎥ ⎥
12 ≈ sol ≈ 32°, 23 ≈ atm ≈ 36-54°, 13 < 15°
would lead to P( ) ≠ P( ). CP
But note the crucial role of s13 sin 13.
cij cos ij
sij sin ij
Atmospheric Cross-Mixing Solar
Majorana CP phases~
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Generically, grand unified models (GUTS) favor —
GUTS relate the Leptons to the Quarks.
is un-quark-like, and would probably involve a lepton symmetry with no quark analogue.
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i
l (le e, l l )
Detector
Ui
The Unitary Leptonic Mixing Matrix U
The component of i that creates l is called , the neutrino of flavor .
The fraction of i is |Ui|2.
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m2atm
e [|Uei|2] [|U i|2] [|Ui|2]
(Mass)2
m2sol}
m2atm
m2sol}
or
The spectrum, showing its approximate flavor content, is
sin213
sin213
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QuickTime™ and aTIFF (Uncompressed) decompressor
are needed to see this picture.
The Open QuestionsThe Open Questions
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How many different neutrino particles are there?
SLAC/CERN Z width result If there are more than 3, then at least one mixture of them does not participate in any of the known forces of nature except gravity.
All known particles participate in some force besides gravity. e, , and participate in the weak nuclear force. An object that doesn’t experience any of the known forces except gravity would be very different.
LSND (Liquid Scintillator Neutrino Detector): There are more than 3 neutrino particles.
MiniBooNE (in progress): Is the LSND experiment right or wrong?
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How much do the neutrino particles 1, 2, and 3 weigh?
Can we use cosmology?
Can observations of the structure of the universe tell us, not just an upper limit on the mass of any neutrino particle, but the
actual masses of these particles?
Can we use laboratory experiments?
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Does the neutrino mass spectrum look like or like ?
Grand Unified Theories: The neutrinos and the charged leptons are cousins of the quarks.
The quark spectra look like .
So, if these theories are right, the neutrino spectrum should look like too.
To find out if it does, pass a beam of neutrinos through more than 500 miles of earth matter.
The behavior of the neutrinos in matter will depend on which kind of a spectrum we have.
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Are neutrinos identical to their antiparticles?
For every particle, there is a corresponding antiparticle.
Particle Antiparticle Electron Positron Electric Charge
Proton Antiproton Electric Charge
Neutron Antineutron Baryonic Charge
Neutrino Antineutrino ??
Difference
Matter Antimatter
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Is there a “leptonic charge” L such that —
L() = L(e–) = –L() = –L(e+) = 1 ?
That would explain why —
e
e–
e
e+
but
But if there is no such leptonic charge, then
there is nothing to distinguish a from a .
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Then, unlike all the other constituents of matter — the charged leptons, and the quarks that make up protons and neutrons — the neutrinos are identical to their antiparticles:
= .
This would make neutrinos very distintive.
How can we confirm that = ?
“Charges,” such as the hypothetical leptonic charge L, are conserved quantities:
ProcessL(in) L(out) = L(in)
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So look for —
New Nucleus
Nucleus
e–
e–
Neutrinoless Double Beta Decay (0)
L = 0
L = 0
L = 1
L = 1
Does not conserve leptonic charge L, so = .
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What is the origin of neutrino mass?
Observation of neutrinoless double beta decay would
The origin of neutrino mass is different from the origin of the masses of electrons, quarks, protons, neutrons, humans, the earth, and galaxies.
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Are neutrinos the reason we exist?The universe contains Matter, but essentially no antimatter.
Good thing for us:
This preponderance of Matter over antimatter could not have developed unless the two behave differently (“CP violation”).
A difference not involving neutrinos has been seen, but it is way too small to explain the universe.
Matter AntimatterPoof!
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Does Matter interact with neutrinos differently than antimatter does?
Could this difference explain the universe?
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There is a natural way in which it could.
The most popular theory of why neutrinos are so light is the —
See-Saw Mechanism
NVery heavy neutrino
Familiar light neutrino
}
{
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The heavy neutrinos N would have been made in the hot Big Bang.
Then they would have disintegrated into lighter particles:
N e- + … and N e+ + …
Matter antimatter
If Matter and antimatter interact differently with neutrinos, both heavy and light, then one of these disintegrations can be more likely than the other.
Then we would get a universe with unequal amounts of Matter and antimatter.
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Can we confirm that Matter and antimatter actually do interact differently with neutrinos?
Source Detector
e- -
Source Detector
e+ +
A neutrino flavor change involving Matter:
A neutrino flavor change involving antimatter:
Do these processes have different rates?
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If N decays led to the present preponderance of Matter over antimatter, then we are all we are all
descendants of heavy neutrinosdescendants of heavy neutrinos.
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Recommendations Recommendations of the APS Multi-of the APS Multi-Divisional StudyDivisional Study
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High priority: Searches for neutrinoless double beta decay, to see if = .
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High priority: A program to —
find out how big the small e-flavored wedge in 3 is
determine whether the mass spectrum looks like or like
search for CP violation in neutrino flavor change
CP violation: Neutrinos interact differently with matter than with antimatter.
There can be no CP violation unless the pie chart for every neutrino particle involves all three colors.
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Important: Develop an experiment that can make detailed studies of the neutrinos from the primary fusion process that we think powers the sun.
These neutrinos have lower energy than those studied in detail so far.
Now that we understand neutrinos much better, we can use them to test whether we truly understand how the sun works.
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Conclusion
There has been an explosion in our knowledge of the neutrinos in the last seven years.
The recent discoveries have raised very interesting questions that we must now try to answer.
Exciting, challenging, experiments to answer them will be launched in the coming years.