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Neutral particle oscillation

From Wikipedia, the free encyclopedia

In particle physics, neutral particle oscillation is the transmutation of a particle with zero electric charge into another neutral particle due to a change of a non-zero internal quantum number, via an interaction that does not conserve that quantum number. Neutral particle oscillations were first investigated in 1954 by Murray Gell-mann and Abraham Pais.[1]

For example, a neutron cannot transmute into an antineutron as that would violate the conservation of baryon number. But in those hypothetical extensions of the Standard Model which include interactions that do not strictly conserve baryon number, neutron–antineutron oscillations are predicted to occur.[2][3][4]

Such oscillations can be classified into two types:

In those cases where the particles decay to some final product, then the system is not purely oscillatory, and an interference between oscillation and decay is observed.

History and motivation

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CP violation

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After the striking evidence for parity violation provided by Wu et al. in 1957, it was assumed that CP (charge conjugation-parity) is the quantity which is conserved.[6] However, in 1964 Cronin and Fitch reported CP violation in the neutral Kaon system.[7] They observed the long-lived KL (with CP = −1 ) undergoing decays into two pions (with CP = [−1]·[−1] = +1 ) thereby violating CP conservation.

In 2001, CP violation in the
B0

B0
system
was confirmed by the BaBar and the Belle experiments.[8][9] Direct CP violation in the
B0

B0
system was reported by both the labs by 2005.[10][11]

The
K0

K0
and the
B0

B0
systems can be studied as two state systems, considering the particle and its antiparticle as two states of a single particle.

The solar neutrino problem

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The pp chain in the sun produces an abundance of
ν
e
. In 1968, R. Davis et al. first reported the results of the Homestake experiment.[12][13] Also known as the Davis experiment, it used a huge tank of perchloroethylene in Homestake mine (it was deep underground to eliminate background from cosmic rays), South Dakota. Chlorine nuclei in the perchloroethylene absorb
ν
e
to produce argon via the reaction

,

which is essentially

.[14]

The experiment collected argon for several months. Because the neutrino interacts very weakly, only about one argon atom was collected every two days. The total accumulation was about one third of Bahcall's theoretical prediction.

In 1968, Bruno Pontecorvo showed that if neutrinos are not considered massless, then
ν
e
(produced in the sun) can transform into some other neutrino species (
ν
μ
or
ν
τ
), to which Homestake detector was insensitive. This explained the deficit in the results of the Homestake experiment. The final confirmation of this solution to the solar neutrino problem was provided in April 2002 by the SNO (Sudbury Neutrino Observatory) collaboration, which measured both
ν
e
flux and the total neutrino flux.[15]

This 'oscillation' between the neutrino species can first be studied considering any two, and then generalized to the three known flavors.

Description as a two-state system

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Special case that only considers mixing

[edit]
Caution: "mixing" discussed in this article is not the type obtained from mixed quantum states. Rather, "mixing" here refers to the superposition of "pure state" energy (mass) eigenstates, prescribed by a "mixing matrix" (e.g. the CKM or PMNS matricies).

Let be the Hamiltonian of the two-state system, and and be its orthonormal eigenvectors with eigenvalues and respectively.

Let be the state of the system at time

If the system starts as an energy eigenstate of for example, say

then the time evolved state, which is the solution of the Schrödinger equation

   (1)

will be[16]

But this is physically same as since the exponential term is just a phase factor: It does not produce an observable new state. In other words, energy eigenstates are stationary eigenstates, that is, they do not yield observably distinct new states under time evolution.

Define to be a basis in which the unperturbed Hamiltonian operator, , is diagonal:

It can be shown, that oscillation between states will occur if and only if off-diagonal terms of the Hamiltonian are not zero.

Hence let us introduce a general perturbation imposed on such that the resultant Hamiltonian is still Hermitian. Then

where and and

   (2)

The eigenvalues of the perturbed Hamiltonian, then change to and where[17]

   (3)

Since is a general Hamiltonian matrix, it can be written as[18]

The following two results are clear:

With the following parametrization[18] (this parametrization helps as it normalizes the eigenvectors and also introduces an arbitrary phase making the eigenvectors most general)

and using the above pair of results the orthonormal eigenvectors of and consequently those of are obtained as

   (4)

Writing the eigenvectors of in terms of those of we get

   (5)

Now if the particle starts out as an eigenstate of (say, ), that is

then under time evolution we get[17]

which unlike the previous case, is distinctly different from

We can then obtain the probability of finding the system in state at time as[17]

   (6)

which is called Rabi's formula. Hence, starting from one eigenstate of the unperturbed Hamiltonian the state of the system oscillates between the eigenstates of with a frequency (known as Rabi frequency),

   (7)

From equation (6), for we can conclude that oscillation will exist only if So is known as the coupling term as it connects the two eigenstates of the unperturbed Hamiltonian and thereby facilitates oscillation between the two.

Oscillation will also cease if the eigenvalues of the perturbed Hamiltonian are degenerate, i.e. But this is a trivial case as in such a situation, the perturbation itself vanishes and takes the form (diagonal) of and we're back to square one.

Hence, the necessary conditions for oscillation are:

  • Non-zero coupling, i.e.
  • Non-degenerate eigenvalues of the perturbed Hamiltonian i.e.

The general case: considering mixing and decay

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If the particle(s) under consideration undergoes decay, then the Hamiltonian describing the system is no longer Hermitian.[19] Since any matrix can be written as a sum of its Hermitian and anti-Hermitian parts, can be written as,

The eigenvalues of are

   (8)

The suffixes stand for Heavy and Light respectively (by convention) and this implies that is positive.

The normalized eigenstates corresponding to and respectively, in the natural basis are

   (9)

and are the mixing terms. Note that these eigenstates are no longer orthogonal.

Let the system start in the state That is

Under time evolution we then get

Similarly, if the system starts in the state , under time evolution we obtain

CP violation as a consequence

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If in a system and represent CP conjugate states (i.e. particle-antiparticle) of one another (i.e. and ), and certain other conditions are met, then CP violation can be observed as a result of this phenomenon. Depending on the condition, CP violation can be classified into three types:[19][21]

CP violation through decay only

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Consider the processes where decay to final states , where the barred and the unbarred kets of each set are CP conjugates of one another.

The probability of decaying to is given by,

,

and that of its CP conjugate process by,

If there is no CP violation due to mixing, then .

Now, the above two probabilities are unequal if,

and    (10)

.

Hence, the decay becomes a CP violating process as the probability of a decay and that of its CP conjugate process are not equal.

CP violation through mixing only

[edit]

The probability (as a function of time) of observing starting from is given by,

,

and that of its CP conjugate process by,

.

The above two probabilities are unequal if,

   (11)

Hence, the particle-antiparticle oscillation becomes a CP violating process as the particle and its antiparticle (say, and respectively) are no longer equivalent eigenstates of CP.

CP violation through mixing-decay interference

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Let be a final state (a CP eigenstate) that both and can decay to. Then, the decay probabilities are given by,

and,

where,

From the above two quantities, it can be seen that even when there is no CP violation through mixing alone (i.e. ) and neither is there any CP violation through decay alone (i.e. ) and thus the probabilities will still be unequal, provided that

   (12)

The last terms in the above expressions for probability are thus associated with interference between mixing and decay.

An alternative classification

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Usually, an alternative classification of CP violation is made:[21]

Direct CP violation Direct CP violation is defined as, In terms of the above categories, direct CP violation occurs in CP violation through decay only.
Indirect CP violation Indirect CP violation is the type of CP violation that involves mixing. In terms of the above classification, indirect CP violation occurs through mixing only, or through mixing-decay interference, or both.

Specific cases

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Neutrino oscillation

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Considering a strong coupling between two flavor eigenstates of neutrinos (for example,
ν
e

ν
μ
,
ν
μ

ν
τ
, etc.) and a very weak coupling between the third (that is, the third does not affect the interaction between the other two), equation (6) gives the probability of a neutrino of type transmuting into type as,

where, and are energy eigenstates.

The above can be written as,

   (13)

where,
, i.e. the difference between the squares of the masses of the energy eigenstates,
is the speed of light in vacuum,
is the distance traveled by the neutrino after creation,
is the energy with which the neutrino was created, and
is the oscillation wavelength.
Proof

where, is the momentum with which the neutrino was created.

Now, and .

Hence,

where,

Thus, a coupling between the energy (mass) eigenstates produces the phenomenon of oscillation between the flavor eigenstates. One important inference is that neutrinos have a finite mass, although very small. Hence, their speed is not exactly the same as that of light but slightly lower.

Neutrino mass splitting

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With three flavors of neutrinos, there are three mass splittings:

But only two of them are independent, because .

For solar neutrinos
For atmospheric neutrinos  

This implies that two of the three neutrinos have very closely placed masses. Since only two of the three are independent, and the expression for probability in equation (13) is not sensitive to the sign of (as sine squared is independent of the sign of its argument), it is not possible to determine the neutrino mass spectrum uniquely from the phenomenon of flavor oscillation. That is, any two out of the three can have closely spaced masses.

Moreover, since the oscillation is sensitive only to the differences (of the squares) of the masses, direct determination of neutrino mass is not possible from oscillation experiments.

Length scale of the system

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Equation (13) indicates that an appropriate length scale of the system is the oscillation wavelength . We can draw the following inferences:

  • If , then and oscillation will not be observed. For example, production (say, by radioactive decay) and detection of neutrinos in a laboratory.
  • If , where is a whole number, then and oscillation will not be observed.
  • In all other cases, oscillation will be observed. For example, for solar neutrinos; for neutrinos from nuclear power plant detected in a laboratory few kilometers away.

Neutral kaon oscillation and decay

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CP violation through mixing only

[edit]

The 1964 paper by Christenson et al.[7] provided experimental evidence of CP violation in the neutral Kaon system. The so-called long-lived Kaon (CP = −1) decayed into two pions (CP = (−1)(−1) = 1), thereby violating CP conservation.

and being the strangeness eigenstates (with eigenvalues +1 and −1 respectively), the energy eigenstates are,

These two are also CP eigenstates with eigenvalues +1 and −1 respectively. From the earlier notion of CP conservation (symmetry), the following were expected:

  • Because has a CP eigenvalue of +1, it can decay to two pions or with a proper choice of angular momentum, to three pions. However, the two pion decay is a lot more frequent.
  • having a CP eigenvalue −1, can decay only to three pions and never to two.

Since the two pion decay is much faster than the three pion decay, was referred to as the short-lived Kaon , and as the long-lived Kaon . The 1964 experiment showed that contrary to what was expected, could decay to two pions. This implied that the long lived Kaon cannot be purely the CP eigenstate , but must contain a small admixture of , thereby no longer being a CP eigenstate.[22] Similarly, the short-lived Kaon was predicted to have a small admixture of . That is,

where, is a complex quantity and is a measure of departure from CP invariance. Experimentally, .[23]

Writing and in terms of and , we obtain (keeping in mind that [23]) the form of equation (9):

where, .

Since , condition (11) is satisfied and there is a mixing between the strangeness eigenstates and giving rise to a long-lived and a short-lived state.

CP violation through decay only

[edit]

The
K0
L
and
K0
S
have two modes of two pion decay:
π0

π0
or
π+

π
. Both of these final states are CP eigenstates of themselves. We can define the branching ratios as,[21]

.

Experimentally, [23] and . That is , implying and , and thereby satisfying condition (10).

In other words, direct CP violation is observed in the asymmetry between the two modes of decay.

CP violation through mixing-decay interference

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If the final state (say ) is a CP eigenstate (for example
π+

π
), then there are two different decay amplitudes corresponding to two different decay paths:[24]

.

CP violation can then result from the interference of these two contributions to the decay as one mode involves only decay and the other oscillation and decay.

Which then is the "real" particle

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The above description refers to flavor (or strangeness) eigenstates and energy (or CP) eigenstates. But which of them represents the "real" particle? What do we really detect in a laboratory? Quoting David J. Griffiths:[22]

The neutral Kaon system adds a subtle twist to the old question, 'What is a particle?' Kaons are typically produced by the strong interactions, in eigenstates of strangeness (
K0
and
K0
), but they decay by the weak interactions, as eigenstates of CP (K1 and K2). Which, then, is the 'real' particle? If we hold that a 'particle' must have a unique lifetime, then the 'true' particles are K1 and K2. But we need not be so dogmatic. In practice, it is sometimes more convenient to use one set, and sometimes, the other. The situation is in many ways analogous to polarized light. Linear polarization can be regarded as a superposition of left-circular polarization and right-circular polarization. If you imagine a medium that preferentially absorbs right-circularly polarized light, and shine on it a linearly polarized beam, it will become progressively more left-circularly polarized as it passes through the material, just as a
K0
beam turns into a K2 beam. But whether you choose to analyze the process in terms of states of linear or circular polarization is largely a matter of taste.

The mixing matrix - a brief introduction

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If the system is a three state system (for example, three species of neutrinos
ν
e

ν
μ

ν
τ
, three species of quarks
d

s

b
), then, just like in the two state system, the flavor eigenstates (say , , ) are written as a linear combination of the energy (mass) eigenstates (say , , ). That is,

.

In case of leptons (neutrinos for example) the transformation matrix is the PMNS matrix, and for quarks it is the CKM matrix.[25][a]

The off diagonal terms of the transformation matrix represent coupling, and unequal diagonal terms imply mixing between the three states.

The transformation matrix is unitary and appropriate parameterization (depending on whether it is the CKM or PMNS matrix) is done and the values of the parameters determined experimentally.

See also

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Footnotes

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  1. ^ N.B.: The three familiar neutrino species
    ν
    e
    ,
    ν
    μ
    , and
    ν
    τ
    , are flavor eigenstates, whereas the three familiar quarks species
    d
    ,
    s
    , and
    b
    , are energy eigenstates.

References

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  1. ^ Gell-mann, M.; Pais, A. (1 March 1955). "Behavior of Neutral Particles under Charge Conjugation". Physical Review. 97 (5): 1385. Bibcode:1955PhRv...97.1387G. doi:10.1103/PhysRev.97.1387.
  2. ^ Mohapatra, R.N. (2009). "Neutron-anti-neutron oscillation: Theory and phenomenology". Journal of Physics G. 36 (10): 104006. arXiv:0902.0834. Bibcode:2009JPhG...36j4006M. doi:10.1088/0954-3899/36/10/104006. S2CID 15126201.
  3. ^ Giunti, C.; Laveder, M. (19 August 2010). "Neutron oscillations". Neutrino Unbound. Istituto Nazionale di Fisica Nucleare. Archived from the original on 27 September 2011. Retrieved 19 August 2010.
  4. ^ Kamyshkov, Y.A. (16 January 2002). Neutron → antineutron oscillations (PDF). Large Detectors for Proton Decay, Supernovae, and Atmospheric Neutrinos and Low Energy Neutrinos from High Intensity Beams. NNN 2002 Workshop. CERN, Switzerland. Retrieved 19 August 2010.
  5. ^ Griffiths, D.J. (2008). Elementary Particles (2nd, Revised ed.). Wiley-VCH. p. 149. ISBN 978-3-527-40601-2.
  6. ^ Wu, C.S.; Ambler, E.; Hayward, R.W.; Hoppes, D.D.; Hudson, R.P. (1957). "Experimental test of parity conservation in beta decay". Physical Review. 105 (4): 1413–1415. Bibcode:1957PhRv..105.1413W. doi:10.1103/PhysRev.105.1413.
  7. ^ a b Christenson, J.H.; Cronin, J.W.; Fitch, V.L.; Turlay, R. (1964). "Evidence for the 2π decay of the K0
    2
    meson"
    . Physical Review Letters. 13 (4): 138–140. Bibcode:1964PhRvL..13..138C. doi:10.1103/PhysRevLett.13.138.
  8. ^ Abashian, A.; et al. (2001). "Measurement of the CP violation parameter sin(2φ1) in B0
    d
    meson decays". Physical Review Letters. 86 (12): 2509–2514. arXiv:hep-ex/0102018. Bibcode:2001PhRvL..86.2509A. doi:10.1103/PhysRevLett.86.2509. PMID 11289969. S2CID 12669357.
  9. ^ Aubert, B.; et al. (BABAR Collaboration) (2001). "Measurement of CP-violating asymmetries in B0 decays to CP eigenstates". Physical Review Letters. 86 (12): 2515–2522. arXiv:hep-ex/0102030. Bibcode:2001PhRvL..86.2515A. doi:10.1103/PhysRevLett.86.2515. PMID 11289970. S2CID 24606837.
  10. ^ Aubert, B.; et al. (BABAR Collaboration) (2004). "Direct CP violating asymmetry in B0 → K+π decays". Physical Review Letters. 93 (13): 131801. arXiv:hep-ex/0407057. Bibcode:2004PhRvL..93m1801A. doi:10.1103/PhysRevLett.93.131801. PMID 15524703. S2CID 31279756.
  11. ^ Chao, Y.; et al. (Belle Collaboration) (2005). "Improved measurements of the partial rate asymmetry in B → hh decays" (PDF). Physical Review D. 71 (3): 031502. arXiv:hep-ex/0407025. Bibcode:2005PhRvD..71c1502C. doi:10.1103/PhysRevD.71.031502. S2CID 119441257.
  12. ^ Bahcall, J.N. (28 April 2004). "Solving the mystery of the missing neutrinos". The Nobel Foundation. Retrieved 2016-12-08.
  13. ^ Davis, R. Jr.; Harmer, D.S.; Hoffman, K.C. (1968). "Search for Neutrinos from the Sun". Physical Review Letters. 20 (21): 1205–1209. Bibcode:1968PhRvL..20.1205D. doi:10.1103/PhysRevLett.20.1205.
  14. ^ Griffiths, D.J. (2008). Elementary Particles (Second, revised ed.). Wiley-VCH. p. 390. ISBN 978-3-527-40601-2.
  15. ^ Ahmad, Q.R.; et al. (SNO Collaboration) (2002). "Direct evidence for neutrino flavor transformation from neutral-current interactions in the Sudbury Neutrino Observatory". Physical Review Letters. 89 (1): 011301. arXiv:nucl-ex/0204008. Bibcode:2002PhRvL..89a1301A. doi:10.1103/PhysRevLett.89.011301. PMID 12097025.
  16. ^ Griffiths, D.J. (2005). Introduction to Quantum Mechanics. Pearson Education International. ISBN 978-0-13-191175-8.
  17. ^ a b c Cohen-Tannoudji, C.; Diu, B.; Laloe, F. (2006). Quantum Mechanics. Wiley-VCH. ISBN 978-0-471-56952-7.
  18. ^ a b Gupta, S. (13 August 2013). "The mathematics of 2-state systems" (PDF). course handout 4. theory.tifr.res.in/~sgupta. Quantum Mechanics I. Tata Institute of Fundamental Research. Retrieved 2016-12-08.
  19. ^ a b Dighe, A. (26 July 2011). "B physics and CP violation: An introduction" (PDF) (lecture notes). Tata Institute of Fundamental Research. Retrieved 2016-08-12.
  20. ^ Sakurai, J.J.; Napolitano, J.J. (2010). Modern Quantum Mechanics (2nd ed.). Addison-Wesley. ISBN 978-0-805-38291-4.
  21. ^ a b c Kooijman, P.; Tuning, N. (2012). "CP violation" (PDF).
  22. ^ a b Griffiths, D.J. (2008). Elementary Particles (2nd, Revised ed.). Wiley-VCH. p. 147. ISBN 978-3-527-40601-2.
  23. ^ a b c Olive, K.A.; et al. (Particle Data Group) (2014). "Review of Particle Physics – Strange mesons" (PDF). Chinese Physics C. 38 (9): 090001. Bibcode:2014ChPhC..38i0001O. doi:10.1088/1674-1137/38/9/090001. S2CID 260537282.
  24. ^ Pich, A. (1993). "CP violation". arXiv:hep-ph/9312297.
  25. ^ Griffiths, D.J. (2008). Elementary Particles (2nd, revised ed.). Wiley-VCH. p. 397. ISBN 978-3-527-40601-2.