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Neutrino Prop erties Before and After KamLAND
S. Pakvasa
a a

and J. W. F. Valle

b

Department of Physics and Astronomy, University of Hawaii, Manoa 2505 Correa Road, Honolulu, Hawaii 96822 USA
b

Instituto de FДsica Corpuscular - C.S.I.C./Universitat de Val`ncia i e http://ific.uv.es/~ahep

Edificio Institutos de Paterna, Apt 22085, E-46071 Val`ncia, Spain e

arXiv:hep-ph/0301061 v2 5 Feb 2003

Abstract We review neutrino oscillation physics, including the determination of mass splittings and mixings from current solar, atmospheric, reactor and accelerator neutrino data. A brief discussion is given of cosmological and astrophysical implications. Non-oscillation phenomena such as neutrinoless double b eta decay would, if discovered, prob e the absolute scale of neutrino mass and also reveal their Ma jorana nature. Non-oscillation descriptions in terms of spin-flavor precession (SFP) and non-standard neutrino interactions (NSI) currently provide an excellent fit of the solar data. However they are at odds with the first results from the KamLAND exp eriment which imply that, despite their theoretical interest, non-standard mechanisms can only play a sub-leading role in the solar neutrino anomaly. Accepting the LMA-MSW solution, one can use the current solar neutrino data to place imp ortant restrictions on non-standard neutrino prop erties, such as neutrino magnetic moments. Both solar and atmospheric neutrino data can also b e used to place constraints on neutrino instability as well as the more exotic p ossibility of C P T and Lorentz Violation. We illustrate the p otential of future data from exp eriments such as KamLAND, Borexino and the up coming neutrino factories in constraining non-standard neutrino prop erties.

Contents
1 Introduction 2 Basic Neutrino Parameters 2.1 2.2 Neutrino Oscillation Parameters . . . . . . . . . . . . . . . . . . . . . . . . The Absolute Scale of Neutrino Mass . . . . . . . . . . . . . . . . . . . . . 4 5 5 8 10

3 Neutrino Oscillations 3.1 3.2 3.3

Solar Neutrinos . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 10 Atmospheric Neutrinos . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 16 Reactor and Accelerator Neutrino Data . . . . . . . . . . . . . . . . . . . . 20 3.3.1 3.3.2 3.3.3 3.3.4 Cho oz and Palo Verde . . . . . . . . . . . . . . . . . . . . . . . . . 20 KamLAND . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 20 K2 K . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 2 2 LSND . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 23

3.4 3.5

Neutrino Oscillations After KamLAND . . . . . . . . . . . . . . . . . . . . 24 Combining LSND Data with the Rest . . . . . . . . . . . . . . . . . . . . . 27 29 31

4 Neutrino Mixing in Cosmology and Astrophysics 5 Non-standard Neutrino Interactions 5.1 5.2

Solar Neutrinos . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 32 Atmospheric Neutrinos . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 33 34

6 Neutrino Magnetic Moments 6.1 6.2

Intrinsic Magnetic Moments . . . . . . . . . . . . . . . . . . . . . . . . . . 34 Spin Flavor Precession . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 36

2

7 Neutrino Decay 7.1 7.2

38

Radiative Decays . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 38 Invisible Neutrino Decays . . . . . . . . . . . . . . . . . . . . . . . . . . . 40 7.2.1 7.2.2 Three-bo dy Decays . . . . . . . . . . . . . . . . . . . . . . . . . . . 40 Two-bo dy Decays . . . . . . . . . . . . . . . . . . . . . . . . . . . . 41 44

8 C P T and Lorentz Violation 8.1 8.2

C P T Violation in Neutrino Oscillations . . . . . . . . . . . . . . . . . . . . 44 Lorentz Invariance Violation in Neutrino Oscillations . . . . . . . . . . . . 48 50

9 Neutrino Physics with Future Experiments 9.1 9.2 9.3 9.4 9.5

Probing Spin Flavor Precession with Borexino . . . . . . . . . . . . . . . . 50 Probing Spin Flavor Precession with KamLAND . . . . . . . . . . . . . . . 51 Constraining Neutrino Magnetic Moments with Borexino . . . . . . . . . . 52 Constraining New Gauge Bosons at Very Low Energies . . . . . . . . . . . 53 Probing Non-Standard Interactions at Neutrino Factories . . . . . . . . . . 54 55

10 Discussion and Outlook

3

1

Introduction

Since the early Davis experiment using the geo chemical metho d to detect solar neutrinos via the e +
37

gone a long way to become now a mature field. The subsequent Gallex [2], Sage [3] and GNO [4] experiments have not only confirmed the consistency of the basic elements of solar energy generation, but also established that the deficit seen in the chlorine experiment also exists in the reaction e +
71

Cl

37

Ar + e- reaction at Homestake [1], solar neutrino research has

techniques using e e scattering on water at Super-K [5], and heavy water at SNO [6, 7] has given a robust confirmation that the number of solar neutrinos detected in these underground experiments is less than expected from theories of energy generation in the sun [8]. Especially relevant is the sensitivity of the SNO experiment to the neutral current (NC). Altogether these experiments provide a solid evidence for solar neutrino conversions and, therefore, for physics beyond the Standard Mo del (SM). Current data indicate that the mixing angle is large [9], the best description being given by the LMA-MSW solution [10], already hinted previously from the flat Super-K recoil electron spectra [11]. We will briefly describe the results of the analysis of solar neutrino data and the resulting parameters in Sec. 3.1. Atmospheric neutrinos are pro duced in hadronic showers initiated by cosmic-ray collisions with air in the upper atmosphere 1 . They have been observed in several experiments [12]. Although individual Е or e fluxes are only known to within 20 - 30% accuracy, their long-standing discrepancy between the predicted and measured Е/e ratio of the muontype (Е + Е ) over the e-type (e + e ) atmospheric neutrino fluxes, has shown up both ? ? in water Cerenkov experiments (Kamiokande, Super-K and IMB) as well as in the iron calorimeter Soudan2 experiment. In addition, a strong zenith-angle dependence has been found both in the sub-GeV and multi-GeV energy range, but only for Е-like events, the zenith-angle distributions for the e-like being consistent with expectation. Such zenithangle distributions have also been recorded for upward-going muon events in Super-K and MACRO, which are also consistent with the Е oscillation hypothesis. The atmospheric neutrino data analysis is summarized in Sec. 3.2.
1

Ga 71 Ge + e- [4]. Direct detection with Cerenkov

ratio is predicted to within 5% over energies varying from 0.1 GeV to tens of GeV [13]. The

See Ref. [9] for an extensive list of experimental references

4

On the other hand, one has information on neutrino oscillations from reactor and accelerator data, discussed in Sec. 3.3. Except for the LSND experiment [14], which claims evidence for e appearance in a Е beam, all of these report no evidence for oscillations. ? ? These experiments include the short baseline disappearance experiments Bugey [15] and CDHS [16], as well as the KARMEN neutrino experiment [17]. Particularly relevant is the non-observation of oscillations at Cho oz and Palo Verde reactors [18], which provides an important restriction on the parameters m22 and sin2 (213 ). 3 Turning now to the new generation of long baseline neutrino oscillation searches, in a recent paper [19] KamLAND has found for the first time strong evidence for the disappearance of neutrinos travelling from a power reactor to a far detector, lo cated at the Kamiokande site. Most of the e flux incident at KamLAND comes from plants lo cated ? meters, long enough to provide a sensitive probe of the LMA-MSW solution of the solar neutrino problem [11]. Therefore these results of the KamLAND collaboration constitute the first test of the solar neutrino oscillation hypothesis with terrestrial experiments and man-pro duced neutrinos. KamLAND also finds the parameters describing this disappearance in terms of the oscillations to be consistent with what is required to account for the solar neutrino problem. As we will comment in Sec. 9 this implies that non-standard solutions can not be leading explanation to the solar neutrino anomaly. On the other hand the K2K experiment has recently observed positive indications of neutrino oscillation in a 250 km long-baseline setup [20]. The collaboration observes a reduction of Е flux together with a distortion of the energy spectrum. The probability that the observed flux at Super-K is a statistical fluctuation without neutrino oscillation is less than 1%. between 80 - 350 km from the detector, making the average baseline of about 180 kilo-

2
2.1

Basic Neutrino Parameters
Neutrino Oscillation Parameters

Current neutrino data require three light neutrinos participating in the oscillations. Correspondingly, the simplest structure of the neutrino sector involves the following parameters: 5

З the solar angle sol 12 (large, but substantially non-maximal) and the solar splitting m21 m2ol 2 s m22 m2tm 3 a

З the atmospheric angle atm 23 (nearly maximal) and the atmospheric splitting m2ol s

З the reactor angle 13 (small) Since in the Standard Mo del neutrinos are massless, their masses must arise from some new physics. An attractive possibility is the seesaw mechanism [21, 22, 23]. However nothing is presently known about whether this is the mechanism pro ducing neutrinos masses and, if so, what is the magnitude of the corresponding mass scale. In fact a more general view is that neutrino masses come from some unknown dimension-five operator [24]. In contrast, neutrino masses could well be generated at the weak scale. One possibility is to have them induced by radiative corrections [25]. Alternatively, neutrino masses may have a supersymmetric origin, resulting from the spontaneous violation of R parity [26]. In this case one is left with a hybrid scheme where only the atmospheric scale comes from a (weak-scale) seesaw, while the solar scale is calculable from radiative corrections [27] 2 . Out of the three neutrino masses, only two splittings are fixed by oscillation data. As will be seen in Secs. 3.1 and 3.2, the neutrino of mass splittings needed to fit the observed solar and atmospheric neutrino anomalies are somewhat hierarchical. Depending on the sign of m22 there are three types of neutrino mass spectra which fit current observation: 3 quasi-degenerate [29, 30, 31], normal, such as typical of seesaw mo dels and bilinear Rparity violation, and inverse-hierarchical neutrino masses. Turning to the three mixing angles, they are a natural feature of gauge theories and follow simply as a result of the fact that in general I=1/2 (up-type) and I=-1/2 (down-type) Yukawa couplings (mass matrices) are not simultaneously diagonal. Typically mixing angles are not predicted from first principles, as we lack a basic theory of flavor. However there has been a flo o d of recent activity in trying to post-dict neutrino mixing angles [30, 31, 32, 33].
2

The idea that neutrino masses arise from broken R parity supersymmetry can be tested at collider

experiments [28]

6

Finally, the simplest structure of the lepton mixing matrix implied by a gauge theory of the weak interaction contains, in addition, three C P violating phases [34, 35]. З one Kobayashi-Maskawa-like C P phase З two Ma jorana-type C P phases The Ma jorana-type phases drop out from L = 0 pro cesses, such as standard oscillations [35, 36]. As for the "Dirac" C P phase, it do es appear in such lepton-number conserving oscillations. However, the corresponding C P violation disappears as two neutrinos become degenerate and/or as one of the angles, e. g. 13 , is set to zero [37]. Given the hierarchical nature of neutrino mass splittings, and the smallness of the mixing angle 13 indicated by reactor experiments (see Sec. 3.3.1) it follows that probing C P violation effects in oscillation experiments will be a very demanding challenge. Therefore all such phases will be neglected in our discussion of solar and atmospheric neutrino oscillations. In addition to the Ma jorana phases, the theoretically expected structure of leptonic weak interactions is substantially more complex in theories where neutrino masses arise from the so-called mechanism [21, 22, 23]. This follows from the fact that such mo dels is rectangular, and the corresponding neutral current (NC) is non-trivial [34]. In other words, the weak CC and NC interactions of neutrinos becomes non-standard. This implies yet additional angles and phases, which may lead to lepton flavor violation, and leptonic C P violation even in the limit where neutrino masses would vanish [38]. This has the important implication that such pro cesses are unrestricted by the smallness of neutrino mass. Given the many possible variants of the see-saw schemes [39], one finds that in some of such mo dels the iso-singlet leptons need not be super-heavy [40], their masses lying at the weak scale or so. This leads to sizeable rates for lepton flavor and leptonic C P violating pro cesses, unrelated to the magnitude of neutrino masses [38]. Insofar as neutrino propagation is concerned, we note that in this class of mo dels the effective CC neutrino mixing matrix is not unitary, with a non-trivial neutrino mixing even in the massless limit [41]. This brings in the possibility of resonant oscillations of massless neutrinos in matter, first noted in [41]. Effectively, neutrino propagation in matter is non-standard, as discussed in Sec. 5. For the time being we neglect all these 7 contain S U (2) U (1) singlet leptons, so that the full charged current (CC) mixing matrix

subtle features in the description of neutrino oscillations we give in Sec. 3. It may also happen that some of the S U (2) U (1) singlet leptons are forced, e. g. by a

protecting symmetry, to remain light enough to participate in the oscillations as sterile

neutrinos [42]. Indeed, while the simplest three-neutrino picture is consistent with all other oscillation searches, it fails to account for the LSND hint [14]. Inclusion of the latter requires, in the framework of the oscillation hypothesis, the existence of a fourth light sterile neutrino taking part in the oscillations [42]. The presence of sterile neutrinos in the oscillations adds another mass parameter, and also increases the number of mixing parameters to six, in addition to C P phases. A detailed parametrization was first given in Ref. [34]. A simple factorization convenient for use in a global analysis of oscillation data is illustrated in Fig. 1.
m2 SOL m2 ATM m2 LSND

SOL

s

ATM
ATM

dЕ

SBL
LSND

e

SOL

Figure 1: Convenient separation of parameter dependence of the different data sets used in Refs. [43, 44]. We will adopt this generalized framework in the description of solar and atmospheric oscillations [9] presented in Secs. 3.1 and 3.2 where we describe, in particular, the constraints implied by both solar and atmospheric data samples on the sterile admixture, s . On the other hand this parametrization will also be employed in the global analysis [44] of all current oscillation data presented in Sec. 3.5.

2.2

The Absolute Scale of Neutrino Mass

Neutrino oscillations are sensitive only to mass splittings, not to the absolute scale of neutrino mass. Probing the latter requires either direct kinematical tests, using tritium beta spectrometers [45], or observations of the Cosmic Microwave Background and large scale 8

structure, sensitive to a sub-leading hot dark matter component [46]. The present limits come from a long list of painstaking efforts to study neutrino mass effects in beta decays, which culminated with the Mainz and Troitsk results (see Ref. [45] for the corresponding references). Given the smallness of the solar and atmospheric mass splittings, the resulting (conservative) bounds on the sum of all neutrino masses [46, 47] are illustrated in the ordinate of Fig. 3. To decide whether neutrinos are Dirac or Ma jorana particles requires the investigation of L = 2 (L denoting lepton-number) pro cesses, of which 0 decay provides the most classic example [48]. Indeed, there is a black-box theorem [49] stating that, in a "natural" gauge theory, the observation of this pro cess would signify the discovery that neutrinos are, as expected by theory [34], Ma jorana fermions. This connection is illustrated by Fig. 2. The importance of this simple argument lies in its generalality: it holds
u d 0 u d

W e

W e

Figure 2: The black-box 0 argument [49]. irrespective of how 0 is engendered. However, in order to quantify its implications, one needs to specify the particular mo del. In the neutrino-exchange-induced mechanism, 0 is characterized by an "effective" neutrino mass parameter Mee whose value is sensitive to possible cancellations among individual neutrino amplitudes. These may arise either as a result of symmetries [50, 51] or due to the Ma jorana-type C P phases [34]. Nevertheless one can show that [52], as illustrated in Fig. 3, there is a direct correlation between Mee and the neutrino mass scales probed in tritium beta decays [47] and cosmology [46]. It is therefore important to probe 0 in a more sensitive experiment [53].

9

100

10

TRITIUM
COSMOLOGY

m (eV)

1

0.1

0.01

0.001

0.01

0.1

1

10

Mee (eV)

Figure 3: 0 and the scale of neutrino mass.

3

Neutrino Oscillations

Although the three-active neutrino oscillation scheme gives a go o d description of both solar and atmospheric data, we will follow the approach given in Ref. [9] in which they are analysed in terms of mixed active-sterile neutrino oscillations. Such generalized scheme has as advantages that it allows one to systematically combine solar and atmospheric data with the current short baseline neutrino oscillation data samples including the LSND evidence for oscillations [44], as done in Sec. 3.5. This is justified, since current reactor bounds on 13 (Sec. 3.3.1) are stronger than solar and atmospheric bounds on the parameter s (with 0 s 1, see Secs. 3.1 and 3.2) describing the fraction of sterile neutrinos taking part in the solar oscillations. By taking such simplified analysis with 13 0, we completely decouple the solar and atmospheric oscillations from each other, and comply trivially with the strong constraints from reactor experiments. For a complementary earlier analysis with 13 = 0 effects, but no sterile neutrinos, see Ref. [54]. As seen in Fig. 1, mixed active-sterile neutrino oscillations are characterized by a total of six mixing angles [34].

3.1

Solar Neutrinos

The solar neutrino data include the solar neutrino rates of the chlorine experiment HomeSAGE [3] (70.8 stake [1] (2.56 Б 0.16 Б 0.16 SNU), the most recent result of the gallium experiments
+5.3 +3.7 -5.2 -3.2

the 1496-days Super-Kamiokande data sample [5]. The latter are presented in the form 10

SNU) and GALLEX/GNO [4] (70.8 Б 4.5 Б 3.8 SNU), as well as

of 44 bins (8 energy bins, 6 of which are further divided into 7 zenith angle bins). In addition to this, we have the latest results from SNO presented in Refs. [6], in the form of 34 data bins (17 energy bins for each day and night perio d). Therefore, in our statistical analysis there are 3 + 44 + 34 = 81 observables. The most popular explanation of solar neutrino experiments is provided by the neutrino oscillations hypothesis. For generality we follow the approach given in Ref. [9] in which they are analysed in terms of mixed active-sterile neutrino oscillations, where the electron neutrino pro duced in the sun converts to x (a combination of Е and ) and a sterile neutrino s : e 1 - s x + s s . In such framework the solar neutrino data are fit with three parameters m2ol , sol s and s . The parameter s with 0 s 1 describes the fraction of sterile neutrinos taking part in the solar oscillations, so that when s 0 one recovers the conventional active oscillation case. The main motivation for adopting such generalized scenarios is the pos-

sibility of combining the solar and atmospheric data with short baseline oscillations [44]. Four-neutrino mass schemes [42] are the most natural candidates to accommo date solar and atmospheric mass-splittings with the hint from LSND [14] indicating a large m2 , see Sec. 3.3. In Fig. 4 we display the regions of solar neutrino oscillation parameters for 3 d.o.f. with respect to the global minimum, for the standard case of active oscillations, s = 0, as well as for s = 0.2 and s = 0.5. The first thing to notice is the impact of the SNO NC, spectral, and day-night data in improving the determination of the oscillation parameters: the shaded regions after their inclusion are much smaller than the hollow
t regions delimited by the corresponding SNOraCe confidence contours. Especially important C

is the full SNO
2 msol > 10 -3

SP,DN CC , N C 2

information in closing the LMA-MSW region from above: values of

eV appear only at 3 . Previous solar data on their own could not close

the LMA-MSW region, only the inclusion of reactor data [18] probed the upper part of the LMA-MSW region [54]. Furthermore, the complete SNOSP,,DN information is important CC N C for excluding maximal solar mixing in the LMA-MSW region. At 3 with 1 d.o.f. one has LMA - MSW : 0.26 tan2 sol 0.85 , 2.6з10
-5

eV2 m2ol 3.3з10 s

-4

eV2 (1)

showing that in the LMA-MSW region tan2 sol is significantly below maximal. Note that in order to compare the allowed regions in Fig. 4 with others [55], one must 11

note that our C.L. regions correspond to the 3 d.o.f. corresponding to tan2 sol , m2ol s and s . Therefore at a given C.L. our regions are larger than the usual regions for 2 d.o.f., because we also constrain the parameter s . Our global best fit point o ccurs for active

msol2 [eV2]

10 10 10 10 10 10 10

-3 -4 -5 -6 -7 -8 -9

10 10 10

-10 -11 -12

s = 0
-1

s = 0.2
1 10
-1

s = 0.5
10
-1

10

1

1
2

10

tan sol
2 Figure 4: Allowed tan2 sol and msol regions for s = 0 (active oscillations), s = 0.2 t and s = 0.5. The lines and shaded regions correspond to the SNOraCe and SNO C SP,DN CC , N C

analyses, respectively, as defined in Ref. [9]. The 90%, 95%, 99% C.L. and 3 contours are for 3 d.o.f.. oscillations with LMA - MSW : tan2 sol = 0.46 , m2ol = 6.6 з 10 s
-5

eV

2

(2 )

A concise way to illustrate the above results is displayed in Fig. 5. We give the profiles of 2ol as a function of m2ol (left), tan2 sol (middle) as well as s (right), by s s minimizing with respect to the undisplayed oscillation parameters. In the left and middle panels the solid, dashed and dot-dashed lines correspond to s = 0, s = 1 and s = 0.5, respectively. The use of the full SNO
SP,DN CC , N C

sample has lead to the relative worsening

of all oscillation solutions with respect to the preferred active LMA-MSW solution. One sees also how the preferred status of the LMA-MSW solution survives in the presence of a small sterile admixture characterized by s . Increasing s leads to a deterioration
2 of all oscillation solutions. Note that in the right panel we display the profile of sol

as a function of 0 s 1, irrespective of the detailed values of the solar neutrino 12

50

40

Sterile Sterile
Just-So
SMA
2

30

2 sol

Mixed
20

Mixed

VAC

95% C.L. (1 d.o.f.)

0 10

LMA
-12

10

-11

10

-10

10

-9

10

-8

10
2 sol

-7

10

-6

10

-5

10

-4

10

-4

10

-3

10

-2

10
2

-1

10

0

0

0.2

0.4

0.6

LMA
0.8

Active

(free

10

3 (1 d.o.f.)

LOW

B)
1

Active

m

tan (sol)

s

sample defined in Ref. [9].

2 2 Figure 5: sol as a function of msol , tan2 sol , and 0 s 1 from global SNOSP,,DN CC N C

oscillation parameters m2ol and sol . One can see that there is a crossing between the s LMA-MSW and VAC solutions. This implies that the best pure-sterile description lies in the VAC regime. However, in the global analysis pure sterile oscillations with s = 1 are highly disfavored. The 2 -difference between pure active and sterile is 2-a = 32.2 if s one restricts to the LMA-MSW solution, or 2-a = 23.3 if one also allows for VAC. For s 3 d.o.f. the 2-a = 23.3 implies that pure sterile oscillations are ruled out at 99.997% s C.L. compared to the active case. For the LMA-MSW solution one can also perform an analysis without fixing the boron flux to its SSM prediction, as seen in the right panel of Fig. 5. One can see that in this case the constraint on s is weaker than in the boron-fixed case, since a smal l sterile component can now be partially compensated by increasing the total boron flux coming from the Sun. From the figure one obtains the bounds solar data : s 0.44 (boron - fixed), s 0.61 (boron - free) (3 )

at 99% C.L. for 1 d.o.f.. A complete table of best fit values of m2ol and sol with s the corresponding 2ol and GOF values for pure active, pure sterile, and mixed neutrino s
t oscillations is given in Ref. [9], both for the SNOraCe (48 - 2 d.o.f.) and the SNOSP,,DN C CC N C

analysis (81 - 2 d.o.f.).

Comparing different solar neutrino analyses Table 1 summarizes a compilation of the results of the solar neutrino analyzes per13

8

formed by the SNO and Super-K collaborations, as well as by different theoretical groups (see Ref. [9] for the references). All groups find the best fit in the LMA-MSW region, although there are quantitative differences even for this preferred solution. As can be seen from the table, the GOF of the best-fit LMA-MSW solution, ranges from 53% to 97%. Generally speaking, one expects the differences in the statistical treatment of the data to have little impact on the global best fit point, lo cated in the LMA-MSW region. These differences typically become more visible as one compares absolute 2 values or departs from the best fit region towards more disfavored solutions. Aware of this, Ref. [9] to ok special care to details such as the dependence of the theoretical errors on the oscillation parameters entering the covariance matrix characterizing the Super-K and SNO electron recoil spectra. This ensures reliability of the results in the full tan2 sol -m2ol plane. s The row labeled "d.o.f." in table 1 gives the number of analyzed data points minus the fitted parameters in each analysis. We also present the best fit values of tan2 sol and m2ol for active oscillations, the corresponding 2 -minima and GOF, as well as the 2 s with respect to the favored active LMA-MSW solution One can see from these numbers how various groups use different experimental input data, in particular the spectral and zenith angle information of Super-K and/or SNO. Despite differences in the analyzes there is relatively go o d agreement on the best fit active LMA-MSW parameters: the best fit values for tan2 sol are in the range 0.34 - 0.47 and for m2ol they lie in the s range (5.0 - 7.9) з 10
-5

eV2 . There is also go o d agreement on the allowed ranges of the
-5

oscillation parameters (not shown in the table). For example, the 3 intervals given in
-5

Bahcall et al (0.24 tan2 sol 0.89, 2.3 з 10 Holanda-Smirnov (tan2 sol 0.84, 2.3 з 10

well with those given in Ref. [9]. There is remarkable agreement on the rejection of the LOW solution with respect to LMA-MSW with a 2 OW L vacuum solution in [9] 2 AC V
,active ,active

eV2 m2ol 3.6 з 10 s

eV2 m2ol 3.7 з 10 s
-4

-4

eV2 ) and

eV2 ) agree very

= 8.6 is in go o d agreement with the values obtained by

10. The result for the

the Super-K collaboration, as well as Bahcall et al, de Holanda & Smirnov and Fogli et al, whereas Bandyopadhyay et al, Barger et al and Creminelli et al obtain higher values. For the SMA-MSW solution one finds 2 M S
A,active

= 23.5, in go o d agreement with the values

obtained in Bahcall et al, Creminelli et al and Fogli et al; while Bandyopadhyay et al and de Holanda & Smirnov, and especially Barger et al, obtain higher values. Typically the results of a given analysis away from the best fit LMA-MSW region serve as an indicator 14

Barranco et al, Ref. [56] 81-2 0.47 5.6 68.0 81% - - -

De Holanda & Smirnov

Sup er-K Collab oration

d.o.f. b est OSC-fit tan2 m
sol

75-3

46

75-3

49-4

80-3

49-2

41-4

81-3

81-3

81-2

active LMA-MSW solution 0.34 5.0 57.0 90% 10.7 - - 0.38 6.9 43.5 58% 9.0 10.0 15.4 0.39 5.6 50.7 97% 9.2 25.6 57.3 0.41 6.1 40.6 66% 10.0 15.5 30.4 0.45 5.8 75.4 53% 9.6 10.1 25.6 0.45 7.9 33.0 94% 8.1 14. 23. 0.40 5.4 30.8 80% - - - 0.41 6.1 65.2 85% 12.4 9.7 34.5 0.42 5.8 73.4 63% 10.0 7.8 23.5 0.46 6.6 65.8 86% 8.7 8.6 23.5

2 sol

[10-5 eV2 ]

2 L MA

GOF
2 LOW 2 VAC 2 SMA

Table 1: Comparison of different solar neutrino analyzes before KamLAND, from Ref. [9]. See text.

15

Maltoni et al, Ref. [9]

Bandyopadhyay et al

SNO Collab oration

Creminelli et al

Bahcall et al

Barger et al

Aliani et al

Fogli et al

of its quality. All in all, in view of the vast input data, of possible variations in the choice of the 2 function and the treatment of errors and their correlations, and of the complexity of the co des involved, it is encouraging that there is reasonable agreement amongst different analyzes, especially for the LMA-MSW solution. As shown in Sec. 3.4, LMA-MSW is now strongly preferred after the results of KamLAND described in Sec. 3.3.2. From this point of view it has now become somewhat academic to scrutinize further the origin of the differences found in the various analyses. Nature has chosen the simplest solution.

3.2

Atmospheric Neutrinos

Here we summarize the analysis of atmospheric data given in a generalized oscillation scheme in which a light sterile neutrino takes part in the oscillations [9]. For simplicity the approximation m2ol s m2tm is used and the electron neutrino is taken as completely a decoupled from atmospheric oscillations, by setting 13 0 (for an analysis with 13 = 0 see [54]). This way we comply with the strong constraints from reactor experiments in Sec 3.3.1. In contrast with the case of solar oscillations, the constraints on the Е -content in atmospheric oscillations are not so stringent. Thus the description of atmospheric neutrino oscillations in this general framework requires two new parameters besides the standard two-neutrino oscillation parameters atm and m2tm . The parameters dЕ and a ds intro duced in Ref. [43] and illustrated in Fig. 1 are defined in such a way that 1 - d
Е

(1 - ds ) corresponds to the fraction of Е (s ) participating in oscillations with m2tm . a ds = 1. In four-neutrino mo dels there is a mass-scheme-dependent relationship between ds and the solar parameter s . For details see Ref. [43].

Hence, pure active atmospheric oscillations with m2tm are recovered when dЕ = 0 and a

therein.

To get a feeling on the physical meaning of these two parameters, note that for dЕ = 0 the Е oscillates with m2tm to a linear combination of and s given as Е ds + a 1 - ds s . For earlier pure active descriptions see, for example, Refs. [57, 58] and papers The global best fit point o ccurs at sin2 atm = 0.49 , m2tm = 2.1 з 10 a 16
-3

eV

2

(4 )

and has ds = 0.92, dЕ = 0.04. One sees that atmospheric data prefers a small sterile neutrino admixture. However, this is not statistically significant, since the pure active case (ds = 1, dЕ = 0) also gives an excellent fit: the difference in 2 with respect to the best fit point is only 2ct- a
best

= 3.3. For the pure active best fit point one obtains,
-3

sin2 atm = 0.5 , m2tm = 2.5 з 10 a with the 3 ranges (1 d.o.f.)

eV

2

(5 )

0.3 sin2 atm 0.7 1.2 з 10
-3

(6 ) (7 )

eV2 m2tm 4.8 з 10 a

-3

eV2 .

The determination of the parameters atm and m2tm is summarized in Figs. 6 and 7. a Note that Fig. 7 considers several cases: arbitrary ds and dЕ , best-fit ds and dЕ , and pure

matm2 [eV ]
2

10

-2

Active [ds=1.0, dЕ=0.0]

Best [ds=best, dЕ=best]

10 10

-3 -2

Mixed [ds=0.5, dЕ=any]

Free [ds=any, dЕ=any]

10

-3

-1

-0.5

0

0.5

-1

-0.5

0

0.5
2

1

sgn(atm) sin atm
Figure 6: Allowed regions of sin2 atm and m2tm at 90%, 95%, 99% and 3 for 4 d.o.f. a and different assumptions on the parameters ds and dЕ , from [9]. The lines (shaded regions) correspond to 1289 (1489) days of Super-K data. active and mixed active-sterile neutrino oscillations, as indicated.
2 At a given C.L. the atm is cut at a 2 determined by 4 d.o.f. to obtain 4-dimensional

volumes in the parameter space of (atm , m2tm , dЕ , ds ). In the upper panels we show a 17

sections of these volumes at values of ds = 1 and dЕ = 0 corresponding to the pure active case (left) and the best fit point (right). Again one sees that moving from pure active to the best fit do es not change the fit significantly. In the lower right panel both dЕ and ds are pro jected away, whereas in the lower left panel ds = 0.5 is fixed and one eliminates only dЕ . Comparing the regions resulting from 1489 days Super-K data (shaded regions) with the one from the 1289 days Super-K sample (hollow regions) we note that the new data leads to a slightly better determination of atm and m2tm . However, more importantly, a from the lower left panel we see how the new data show a much stronger rejection against a sterile admixture: for ds = 0.5 no allowed region appears at 3 for 4 d.o.f..
40

Mixed

Mixed

30

Restricted

2 atm

20

Free
3 (1 d.o.f.) 95% C.L. (1 d.o.f.)

Free

Active

Active

10

Free
0 10
-3

Free

m

2 atm

[eV ]

2

10

-2

-1

-0.5

0
2

0.5

10

0.2

0.4

0.6

0.8

10

0.05

0.1

0.15

0.2

0.25

sgn(atm) sin (atm)

ds

dЕ

Figure 7: 2tm as a function of m2tm , sin2 atm , ds and dЕ . In each panel the undisa a played parameters are integrated out. The "Mixed" and "Restricted" cases correspond to ds = 0.5 and dЕ = 0, respectively [9]. The excellent quality of the neutrino oscillation description of the present atmospheric neutrino data can be better appreciated by displaying the zenith angle distribution of atmospheric neutrino events, given in Fig. 8. Clearly, active neutrino oscillations describe the data very well indeed. In contrast, the no-oscillations hypothesis can be visually spotted as being ruled out. On the other hand, conversions to sterile neutrinos lead to an excess of events for neutrinos crossing the core of the Earth, in all the data samples except sub-GeV.

18

500 400

250 200 150 100 50 1 0 -1 4 -0.5

# events

SK-1489
No oscillations Best [ds=0.92, dЕ=0.04] Active [ds=1.0, dЕ=0.0] Sterile [ds=0.0, dЕ=0.0]

300 200 100

SK sub-GeV (Е)
0 -1 1 -0.5 0 0.5

SK multi-GeV (Е)
0 0.5 1 6

cm s sr )

-1

0.8 0.6

-2

-1

3

5 4

2 0.4 0.2 1

Е (10

-13

3 2

SK stop (Е)
0 -1 -0.8 -0.6 -0.4 -0.2 0 0 -1 -0.8 -0.6

SK thru (Е)
-0.4 -0.2 0

1 0 -1 -0.8

MACRO thru (Е)
-0.6 -0.4 -0.2 0

cos

cos

cos

Figure 8: Zenith angle dependence of the Е-like atmospheric neutrino data from Ref. [9]. The predicted number of atmospheric neutrino events for best-fit, pure-active and pure- sterile oscillations and no oscillations are given, for comparison.

19

3.3
3.3.1

Reactor and Accelerator Neutrino Data
Chooz and Palo Verde

The Cho oz experiment has been the first relatively long-baseline reactor neutrino experiment. As used in Ref. [43], the measured e survival probability from these experiments ? are P = 1.01 Б 0.028 Б 0.027 for Cho oz, and P = 1.01 Б 0.024 Б 0.053 for Palo Verde [18]. m22 and sin2 (213 ), as illustrated in Fig. 9. The curves represent the 90, 95 and 99% CL 3 The non-observation of oscillations at these reactors provides an important restriction on

Figure 9: Region in m22 and sin2 (213 ) excluded by the Cho oz reactor, from [54]. 3 excluded region defined with 2 d. o. f. for comparison with the Cho oz published results.
2 For large m22 this gives a stringent limit on sin2 (213 ), but not for low m32 values. 3

Together with atmospheric data this implies that 13 must be rather small. As will be seen below m2tm a mass splittings. m2ol , i. e. one has a somewhat hierarchical structure of neutrino s

3.3.2

KamLAND

In the KamLAND reactor neutrino experiment the target for the e flux consists of a ? spherical transparent ballo on filled with 1000 tons of non-doped liquid scintillator. The anti-neutrinos are detected via the inverse neutron -decay e + p e+ + n . ? 20 (8 )

The spectral data are given in 13 bins of prompt energy above 2.6 MeV in Fig. 5 of Ref. [19]. There have been already several papers analysing the first results of the KamLAND experiment, here we follow Ref. [59]. The KamLAND data are simulated by calculating the expected number of events in each bin for given oscillation parameters as Nith (m2 , ) = f dE (E )
j

j (E )Pj (E , m2 , )

i

dEe R(Ee , Ee ) .

(9 )

Here R(Ee , Ee ) is the energy resolution function and Ee , Ee are the observed and the true positron energy, respectively, and an energy resolution of 7.5%/ E (MeV) is assumed [19]. The neutrino energy is related to the positron energy by E = Ee + , where is the neutron-proton mass difference. The integration interval over Ee is determined by the prompt energy interval in each bin. The neutrino spectrum (E ) from nuclear reactors is well known, the phenomenological parameterization given in Refs. [60, 61] has been used. The average fuel composition for the nuclear reactors given in Ref. [19] is adopted and possible effects due to time variations in the fuel composition have been neglected [61]. The sum over j in Eq. (9) runs over 16 nuclear plants, taking into account the different distances from the detector and the power output of each reactor (see Table 3 of Ref. [62]). The relevant detection cross section (E ) is given in Ref. [63]. In the two-neutrino framework the disappearance probability for the neutrinos coming from the reactor j is given by Pj (E , m2 , ) = 1 - sin2 2 sin
2

m2 Lj . 4E

(1 0 )

The normalization factor f in Eq. (9) is determined in such a way that for the case of no oscillations the total number of events is 86.8, as expected from the Monte-Carlo simulation used in Ref. [19]. For the statistical analysis one uses the 2 -function 2 =
i,j

(Nith - Niobs )S

-1 ij

(Njth - Njobs ) .

(1 1 )

The observed number of events Njobs in each bin can be read off from Fig. 5 of Ref. [19]. In the covariance matrix one includes the statistical errors (obtained from the same figure) and the systematic error implied by the 6.42% uncertainty on the total number of events expected for no oscillations [19]. 21

10

-3

10

-4
#

m [eV ]
10
-5

2

2

10 0

-6

0.2

0.4
2

0.6

0.8

1

sin (2)

Figure 10: Allowed regions at 90%, 95%, 99% and 99.73% C.L. (2 d.o.f.) from KamLAND spectral data. The solid (dashed) line is the 95% C.L. (3 ) region from the KamLAND rate alone. The star (dot) is the best fit point from the spectral (rate) analysis, from Ref. [59]. In Fig. 10 we show the allowed regions of the oscillation parameters obtained from our re-analysis of the KamLAND data. It is in go o d agreement with the analysis performed by the KamLAND collaboration, shown in Fig. 6 of Ref. [19]. After this successful calibration we turn to a full global analysis combining also with the solar data sample of Sec. 3.4.

3.3.3

K2K

Further evidence for the atmospheric neutrino anomaly has now come from the K2K experiment [20] using accelerator neutrinos in a long-baseline set-up. The collaboration sees a reduction of the Е flux together with a distortion of the energy spectrum. They observe 56 beam neutrino events 250 km away from the neutrino pro duction point, with an expectation of 80.1
+6.2 -5.4

. They also reconstruct the neutrino energy spectrum, which

fits better the expected shape with neutrino oscillation than without. The probability that the observed flux at Super-K is a statistical fluctuation without neutrino oscillation is less than 1%. The collaboration performs a two-neutrino oscillation analysis, with Е disappearance, using the maximum-likeliho o d metho d, and including both the number of events and the energy spectrum shape. The results are given in Fig. 11 and agree nicely with what is

22

m (eV )
2 2
-2

10

-3

10

-4

10

0

0.2

0.4

0.6

0.8 1 2 sin 2

Figure 11: Allowed regions of oscillation parameters from the K2K data of Ref. [20]. Dashed, solid and dot-dashed lines are 68.4%, 90% and 99% C.L. contours, respectively. The best fit point is indicated by the star. inferred from the atmospheric analysis, Sec. 3.2.

3.3.4

LSND

The Liquid Scintillating Neutrino Detector (LSND) is an experiment designed to search for neutrino oscillations in appearance channels. It is the only short baseline accelerator neutrino experiment claiming evidence for oscillations. Here we compare the implications of two different analyses of the LSND data. The first uses the likeliho o d function obtained in the final LSND analysis [14] from their global data with an energy range of 20 < Ee < 200 MeV and no constraint on the likeliho o d ratio R (see Ref. [14] for details). This sample contains 5697 events including decay-atrest (DAR) Е e , and decay-in-flight (DIF) Е e data. We refer to this analysis ? ? as LSND global. The second corresponds to the LSND analysis performed in Ref. [64] cut of R > 10-5 . These cuts eliminate most of the DIF events from the sample, leaving mainly the DAR data, which are more sensitive to the oscillation signal. We refer to this analysis as LSND DAR. In both cases the likeliho o d function obtained in the analyses of the LSND collaboration was used and this was converted into a 2 according to 2 -2 ln L (see Ref. [43] for 23

based on 1032 events obtained from the energy range 20 < Ee < 60 MeV and applying a

10

1

mLSND [eV ]

2

LSND DAR 10
0

2

10

-1

LSND global
-3 -2 2 -1

10

10

10
LSND

1

sin 2

Figure 12: Comparison of the 99% C.L. regions of the global LSND analysis [14] (shaded region) and of the analysis in Ref. [64] (solid line) using the decay-at-rest (DAR) sample. From Ref. [44] details). In Fig. 12 we compare the 99% C.L. regions obtained from the two LSND analyses. The LSND DAR data prefers somewhat larger mixing angles, which will lead to a stronger disagreement of the data in (3+1) oscillation schemes (see below). Furthermore, the differences in 2 between the best fit point and no oscillations for the two analyses are given by 2 o n
osc

= 29 (global) and 2 o n

osc

= 47 (DAR). This shows that the information

leading to the positive oscillation signal seems to be more condensed in the DAR data. Note that the detailed information from the short baseline disappearance no-evidence experiments Bugey [15] and CDHS [16] has been fully taken into account. Concerning the constraints from KARMEN [17], they are included by means of the KARMEN likeliho o d function.

3.4

Neutrino Oscillations After KamLAND

There has been a rush of recent papers on the analysis of neutrino data after KamLAND in the framework of the neutrino oscillation hypothesis (assuming, of course, C P T invariance) [59, 65]. Here we discuss the results of the analysis presented in Ref. [59], to which the reader is referred for the details. Figs. 13 and 14 summarize the results obtained in a combined fit of the full KamLAND data sample with the global sample of solar neutrino data (the same as used in Ref. [9]), as well as the Cho oz result. 24

10

-3

m [eV ]

2

2

10

-4
#

10

-5

10

-1

10

0

tan

2

Figure 13: Allowed regions at 90%, 95%, 99% and 99.73% C.L. (2 d.o.f.) from the combined analysis of solar, Cho oz and KamLAND data. The hollow lines are the allowed regions from solar and Cho oz data alone. The star (dot) is the best fit point from the combined (solar+Cho oz only) analysis from Ref. [59]. First of all, we have quantified the rejection of non-LMA solutions and found that it is now more robust. For example, for the LOW solution one has 2 = 26.9, which for 2 d.o.f. (m2ol and ) lead to a relative probability of 1.4 з 10-6 . A similar result is s also found for the VAC solution. Besides selecting out LMA-MSW as the unique solution impact on the lo cation of the best fit point: tan2 = 0.46,
2 msol = 6.9 з 10 -5

of the solar neutrino problem we find, however, that the new reactor results have little

eV2 .

(1 2 )

In particular the solar neutrino mixing remains significantly non-maximal, a point which is not in conflict with the fact that KamLAND data alone prefer maximal mixing [19], since this has no statistical significance [59]. Indeed, one can see from the right panel in Fig. 14 that 2 is rather flat with respect to the mixing angle for tan2 > 0.4. This explains why the addition of the KamLAND data has no impact whatso ever in the determination of the solar neutrino oscillation mixing. The allowed 3 region one finds for is: 0.29 tan2 0.86, essentially the same as the pre-KamLAND range given in Eq. (1). 25 (1 3 )

20
Global Reactor KamLAND

15

2

10

99.73% C.L. (1 d.o.f.)

5

0 -6 10

10

-5

10
2 2

-4

10

-3

10

-1

10

0

m [eV ]

tan ()

2

Figure 14: 2 versus m2ol and tan2 . The red dashed line refers to KamLAND alone. s The green dot-dashed line corresponds to the full reactor data sample, including both KamLAND and Cho oz. The blue solid line refers to the global analysis of the complete solar and reactor data, from Ref. [59]. Note that the solar mixing angle is large, but significantly non-maximal, in contrast to the atmospheric mixing, Eq. (5). This important fact implies that mo dels where the solar mixing is non-maximal [30] are strongly preferred over bi-maximal mixing mo dels [31]. Turning to the solar neutrino mass splittings, the new data do have a strong impact in narrowing down the allowed m2ol range. From the left panel of Fig. 14 one can s see that the KamLAND data alone provides the bound m2ol > 8 з 10 s the CHOOZ experiment gives m2ol < 10 s
-3 -6

eV2 , whereas

eV2 , both at 3 . Hence global reactor

neutrino data provide a robust allowed m2ol range, based only on terrestrial experiments. s However, combining this information from reactors with the solar neutrino data leads to a significant reduction of the allowed range: As clearly visible in Fig. 13, the pre-KamLAND LMA-MSW region is now split into two sub-regions. At 3 (1 dof.) one obtains 5.1 з 10
-5

eV2 m2ol 9.7 з 10 s

-5

eV2 , 1.2 з 10

-4

eV2 m2ol 1.9 з 10 s

-4

eV2 . (14)

This remaining ambiguity might be resolved when more KamLAND data have been collected [61, 66, 67].

26

3.5

Combining LSND Data with the Rest

A possible confirmation of the LSND anomaly would have remarkable implications. The most obvious would be the need for a sterile neutrino, which should be light enough to participate in the oscillations [42]. There are two classes of four-neutrino mo dels, (3+1) and (2+2): in the first the sterile neutrino can decouple from both solar and atmospheric oscillations, while in the more symmetric (2+2) schemes, it can not decouple from both sectors simultaneously [43]. As a result (2+2) schemes are now more severely rejected by a global analysis 3 . Fig. 15 shows the profiles of 2ol , 2tm s a
40 atm+SBL solar global

2 PG

+sbl

and 2l ?g

obal

as a function

30

2

20

2 PC

10

0

0

0.2

0.4
s

0.6

0.8

1

Figure 15: Excluding joint (2+2) oscillation descriptions of current neutrino data including LSND, from Ref. [44]. of s in (2+2) oscillation schemes, as well as the values 2 C and 2 P P
G

relevant for the

parameter consistency and parameter g.o.f. tests proposed in Ref. [44]. The application of these tests to quantify the compatibility of LSND data with the remaining neutrino oscillation data in (3+1) schemes is illustrated in Fig.16. In the upper panel of Fig.16 we show the C.L. of the parameter consistency, whereas in the lower panel we show the parameter g.o.f. for fixed values of m2snd . The analysis is performed both for the global l [14] and for the DAR [64] LSND data samples. One sees that there is a slim chance to
3

Although KamLAND data are not included here, presently they have essentially no impact on the

results presented in this section

27

10 10 10 10 10 10 10

-1

2 parameter consistency

-2

3

-3

1 - CL

-4

4

-5

-1

2
parameter goodness of fit 3

LSND DAR LSND global

-2

parameter GOF

10 10 10 10 10

-3

-4

4

-5

-6

-7

0.1

1
2 mLSND

10 [eV ]
2

Figure 16: Compatibility of LSND with solar+atmospheric+NEV data in (3+1) schemes, from Ref. [44].

28

reconcile LSND data with the remaining data, provided m2snd is close to 6 eV2 or so, l but only at the expense of having a rather po or description. In conclusion one finds that, though 4-neutrino mo dels can not be ruled out per se, the resulting global description of current neutrino oscillation data is extremely po or, even in the case of (3+1) schemes [44]. We can only wait eagerly for news from the upcoming MiniBo oNE experiment. Fortunately this experiment has began collecting data in the last summer. If it turns out that MiniBo oNE ultimately confirms the LSND claim we will face a real challenge.

4

Neutrino Mixing in Cosmology and Astrophysics

Neutrino flavour mixing usually has no observational consequences in Cosmology [68] because in the standard cosmological mo del all three neutrino flavours were pro duced in the early universe with identical spectra, and thus with the same energy and number densities. However, it could be that any of the neutrino chemical potentials was initially non-zero, or equivalently that a relic asymmetry between neutrinos and antineutrinos existed, which in turn increases the neutrino energy density and constitutes an extra radiation density. Only mild bounds on neutrino asymmetries exist from the analysis of CMBR anisotropies, while Primordial Big Bang Nucleosynthesis (BBN) places a more restrictive limit on the electron neutrino chemical potential, because the e participates ? directly in the beta pro cesses that determine the primordial neutron-to-proton ratio. As seen in Sec. 3.4, the KamLAND data have essentially fixed that neutrino oscillations explain the Solar Neutrino Problem with parameters in the LMA-MSW region. It was shown in Ref. [69] that this result, combined with the evidence of oscillations of atmospheric neutrinos, implies that effective flavour equilibrium is established between all active neutrino species before BBN. Therefore the BBN constraints on the electron neutrino asymmetry apply to all flavours, which in turn implies that neutrino asymmetries do not significantly contribute to the extra relativistic degrees of freedom. Thus the number density of relic neutrinos is very close to its standard value, in such a way that future measurements of the absolute neutrino mass scale, for instance in the forthcoming tritium decay experiment KATRIN [45], will provide unambiguous information on the

29

cosmic mass density in neutrinos, free of the uncertainty of neutrino chemical potentials. If non-active light neutrino species exist, as suggested by the LSND data, then they are resrticted also by BBN [70]. However, this is less relevant now that the terrestrial data themselves disfavor the light sterile neutrino oscillation hypothesis. Back to three-neutrinos, the effect of large solar neutrino mixing in astrophysics can be more substantial. First we note that the large solar mixing angle opens the possibility of probing the noisy character of the deep solar interior [71], especially if an improved determination of m2ol is available from further KamLAND data. s Turning now to supernova neutrino spectra [72], LMA-MSW neutrino conversions in a supernova environment induce a significant deformation of the energy spectra of neutrinos [73]. Despite this fact, a global analysis of SN1987A and solar neutrino observations establishes the consistency of the LMA-MSW solution [74]. Nevertheless, the large solar mixing angle do es have a strong impact on strategies for diagnosing collapse-driven supernovae through neutrino observations, opening new ways to probe supernova parameters. Indeed, fixing the LMA-MSW solution, one may in the future probe otherwise inaccessible features of supernova neutrino spectra such as the temperatures and luminosities of non-electron flavor neutrinos [75]. This can be done simply by observing e 's from galactic supernovae through the charged current reactions ? on protons, using massive water Cherenkov detectors. As an illustration we present Fig. 17 different 3 contours for Super-K and Hyper-K, calculated both for the case of LMAMSW conversions and no-oscillations. Best fits are indicated by the stars. The plots
0 0 result from a simulation which uses Ee = 15 MeV, 0 = 1.4 and Eb = 3 з 10 ? 53

erg as

input supernova parameters. Details in Ref. [75].

Recent simulations indicate, however, that although the value of 0 may be substantially lower than what has been optimistically assumed in Ref. [75], the fluxes of different flavors of supernova neutrinos may differ [76], giving an additional handle on the diagnostic of supernovae through neutrino observations. In addition to oscillations, other types of neutrino flavor conversions can affect the propagation of neutrinos in a variety of astrophysical environments, such as supernovae. For example, neutrino non-standard interactions, discussed in Sec. 5, could lead to resonant oscillations of massless neutrinos in matter [41]. These could lead to "deep-inside" 30

4.5
LMA SK LMA HK NO OSC SK NO OSC HK

1.6 1.55 1.5 1.45
LMA SK LMA HK NO OSC SK NO OSC HK

4

Eb [10 erg]

3.5

E
3 2.5 2 14 14.5 15 15.5 16

1.4 1.35 1.3 1.25 1.2 14 14.5 15 15.5 16

53

e

e

1.6 1.55 1.5
LMA SK LMA HK

4.5
LMA SK LMA HK NO OSC SK

4

Eb [10 erg]

1.45

3.5

E

1.4 1.35 1.3 1.25 1.2 0 0.2 0.4 0.6 0.8 1 1.2

53

3

2.5

2

0

0.2

0.4

0.6

0.8

1

1.2

Figure 17: Probing supernova spectra through LMA-MSW oscillations, from Ref. [75] conversions [77], rather distinct from those expected from conventional neutrino oscillations [78]. Another possibility are flavor conversions due to decays of neutrinos, discussed in Sec. 7. If neutrino masses arise from the spontaneous violation of ungauged leptonnumber, they are accompanied by a physical Goldstone boson, the ma joron [23]. In the high-density supernova medium the effects of ma joron-emitting neutrino decays are important even if they are suppressed in vacuo by small neutrino masses and/or small off-diagonal couplings. Such strong enhancement is due to matter effects, and implies that ma joron-emitting decays have an important effect on the neutrino signal of supernovae [79]. ma joron-neutrino coupling constants in the range 3 з 10 o r g > 3 з 1 0-4 improved sensitivity from a future galactic supernova. < g < 2 з 1 0-5 are excluded by the observation of SN1987A, and could be probed with
-7

5

Non-standard Neutrino Interactions

Non-standard neutrinos interactions (NSI) are a natural feature in most neutrino mass mo dels [34, 39]. They can be of two types: flavour-changing (FC) and non-universal (NU). The co-existence of neutrino masses and NSI in many mo dels of neutrino mass 31

means that neutrino flavor transformations may be induced by both and therefore ideally both should be taken into account when analysing neutrino data. NSI may be schematically represented as effective dimension-6 terms of the type GF , as illustrated in Fig. 18, where specifies their sub-weak strength. Such interactions

e, u, d

e, u, d

Figure 18: Effective NSI operator. may arise from a nontrivial structure of CC and NC weak interactions characterized a non-unitary lepton mixing matrix and a correspondingly non-trivial NC matrix [34]. Such gauge-induced NSI may lead to flavor and C P violation, even with massless (degenerate) neutrinos [40]. In radiative mo dels where neutrino mass are "calculable" [25] and supersymmetric mo dels with broken R parity [26, 80] FC-NSI can also be Yukawa-induced, from the exchange of spinless bosons. In supersymmetric unified mo dels, NSI may be calculable renormalization effects [81]. We now describe the impact of non-standard neutrino interactions on solar and atmospheric neutrinos. Since the NSI strengths are highly mo del-dependent, we treat them as free phenomenological parameters.

5.1

Solar Neutrinos

At the moment one can not yet pin down the exact profile of the e survival probability over the whole spectrum and, as a result, the underlying mechanism of solar neutrino conversion remains unknown. Thus non-oscillation solutions, such as those based on non-standard neutrino matter interactions can be envisaged. As already mentioned, an important feature of the NSI-induced conversions [41] is that the conversion probability is energy-independent. This implies that the solar neutrino energy spectrum is undistorted, as indeed preferred by the Super-K and SNO spectrum data. In the first paper in Ref. [82] it has been shown how NSI provide an excellent description of present solar neutrino data. The allowed regions for the NSI mechanism of solar neutrino conversion are shown in Fig. 19. Although the required magnitude of NU 32

Е

?

interaction is somewhat large, it is not in conflict with current data 4 . Moreover one sees
2 , eff / c13
0.45 0.44 0.43 0.42 0.41 0.4

0.44 0.43 0.42 0.41 0.4

sin 13 = 0.02
2

sin 13 = 0.1
2

sin 13 = 0.3
2

sin 13 = 0.5
2

10

-3

10

-2

10

-1

10

-3

10

-2

10

-1

10

-3

10

-2

10

-1

10

-3

10

-2

eff

10

Figure 19: Up-type quark NSI parameters needed to solve the solar neutrino anomaly, from the first of Ref. [82]. that the amount of FC interaction indicated by the best fit is comfortably small. Such a pure NSI description of solar data with massless and unmixed neutrinos is slightly better than that of the favored LMA-MSW solution, and the NSI values indicated by the solar data analysis do not upset the successful oscillation description of the atmospheric data [82]. This establishes the overall consistency of a hybrid scheme in which only atmopsheric data are explained in terms of neutrino osciillations. However, the recent first results of the KamLAND collaboration [19] reject non-oscillation solutions, such as those based on NSI, at more than 3 so that the NSI effect in solar neutrino propagation must be sub-leading. Accepting the LMA-MSW solution one may determine restrictions on NSI parametetrs and, therefore, on new aspects of neutrino mass mo dels.

5.2

Atmospheric Neutrinos

Flavor-changing non-standard interactions (FC-NSI) in the Е - channel have been shown to account for the zenith-angle-dependent deficit of atmospheric neutrinos ob4

Note that there are no stringent direct bounds on NSI involving neutrinos, only for the charged

leptons. However, the latter do not directly apply to the neutriunos case, hence the importance of the atmopsheric data

33

Rates + Sp-Zen
-1

0.45

Rates only

sin 13 = 0.0
2

sin 13 = 0.1
2

sin 13 = 0.3
2

sin 13 = 0.5
2

served in contained Super-K events [83]. The solution works even in the absence of neutrino mass and mixing. However such pure NSI explanation fails to reconcile these with Super-K and MACRO up-going muons, due to the lack of energy dependence intrinsic of NSI conversions. The discrepancy is at the 99% C.L. [57]. Thus, unlike the case of solar neutrinos, the oscillation interpretation of atmospheric data is robust, NSI being allowed only at a sub-leading level. Such robustness of the atmospheric Е oscillation hypothesis can be used to provide the most stringent current limits on FC and NU neutrino interactions, as illustrated in Fig. 20. These limits are rather mo del-independent, as

Figure 20: Atmospheric bounds on neutrino NSI with down-type quarks [57]. they are obtained from just neutrino-physics pro cesses. As described in Sec. 9.5, future neutrino factories can probing non-standard neutrino interactions in this channel with better sensitivity.

6
6.1

Neutrino Magnetic Moments
Intrinsic Magnetic Moments

Non-zero neutrino masses can manifest themselves through non-standard neutrino electromagnetic properties. When the lepton sector in the Standard Mo del (SM) is minimally extended as in the quark sector, neutrinos get Dirac masses (m ) and their magnetic moments (MMs) are tiny [84], Е

3 з 10

-19

Е

B

m 1 eV
-10

,

(1 5 )

where ЕB is the Bohr magneton. Laboratory experiments give 90%C.L. bounds on the neutrino MMs of 1.8 з 10
-10

ЕB [85] and 1.3 з 10 34

ЕB [86, 87] for the electron neutrino.

These are summarized in Fig. 21. For the muon neutrino the bound is 6.8 з 10
4.5 4 3.5 3 2.5 2 1.5 1 0.5

-10

Е

B

1

10

10

2

10

3

Figure 21: Summary of the results in the searches of neutrino magnetic moments with reactor neutrinos, from Ref. [86]. [88] and 3.9 з 10-7 ЕB for the tau neutrino [89] (see also Ref. [47]). On the other hand,
12

astrophysics and cosmology provide limits of the order of 10-

to 1 0

-11

Bohr magnetons
-12

[90]. Improved sensitivity for the electron neutrino from reactor neutrino searches is expected, while a tritium e source experiment [91] aims to reach the level 3 з 10 ? ЕB .

It has for a long time been noticed, on quite general "naturality" grounds, that Ma jorana neutrinos constitute the typical outcome of gauge theories [34]. On the other hand, precisely such neutrinos also emerge in specific classes of unified theories, in particular, in those employing the seesaw mechanism [21, 22, 23]. If neutrinos are indeed Ma jorana particles the structure of their electromagnetic properties differs crucially from that of so-called Ma jorana transition moment (TM) matrix. It contains MMs as well as electric dipole moments of the neutrinos. The existence of any electromagnetic neutrino moment well above the expectation in Eq. (15) would signal the existence of physics beyond the SM. Thus neutrino electromagnetic properties sre sensitive probes of new physics. Majorana TMs play an especially interesting role. As we will describe next, they can affect neutrino propagation in an important way and, to that extent, play an important in cosmology and astrophsyics. Dirac neutrinos [92], being characterized by a 3 з 3 complex anti-symmetric matrix , the

35

6.2

Spin Flavor Precession

Although LMA-MSW conversions are clearly favored over other oscillation-type solutions, current solar neutrino data by themselves are not enough to single out the mechanism of neutrino conversion responsible for the suppression of the signal. Magnetic-moment-induced neutrino conversions [84] in the convective zone of the Sun [93] have been long suggested as a potential solution of the solar neutrino problem. However, this would require to o large neutrino magnetic moment and also that neutrinos are Dirac particles, favored neither by theory [21, 22, 23] nor by astrophysics [94]. As a result here we fo cus on the preferred case of Spin-flavor Precession (SFP) [92, 95]. A global analysis of spin-flavour precession solutions to the solar neutrino problem, taking into account the impact of the full set of latest solar neutrino data, including the recent SNO-NC data as well as the 1496-day Super-Kamiokande data has been given in Ref. [56]. These solutions depend in principle on the magnetic field profile. It is very convenient to adopt a self-consistent form for the static magnetic field profile [96, 97] motivated by magneto-hydro dynamics. With this one finds that, to a go o d approximation, the dependence of the neutrino SFP probabilities on the magnetic field gets reduced to an effective parameter ЕB characterizing the maximum magnetic field strength in the convective zone. This way one is left with just three parameters: m2ol m2 , the s neutrino mixing angle sol and the parameter ЕB . For Е = 10 the lowest optimum B value is 80 KGauss.
-11

Bohr magneton

Fig. 22 shows the resulting parameter regions as given in [56]. One finds that, in addition to the standard LMA-MSW solution, there are two SFP solutions, in the resonant (RSFP) and non-resonant (NRSFP) regimes [97], with LOW-quasi-vacuum or vacuum solutions absent at the 3 sigma level [56]. Note that in the presence of a neutrino transition magnetic moment of 10-
11

Bohr magneton, a solar magnetic field of 80 KGauss eliminates

all oscillation solutions other than LMA-MSW, irrespective of KamLAND results. On the other hand Fig. 23 shows the predicted solar neutrino survival probabilities for the "best" LMA-MSW solution, and for the "best" SFP solutions, from latest solar data. Clearly the spectra in the high energy region are nearly undistorted in all three cases, in agreement with observations. As far as the solar neutrino data are concerned, one finds that the two SFP solutions give a slightly lower 2ol than LMA-MSW, though all three solutions are s 36

Figure 22: Allowed m2ol and tan2 sol for RSFP, LMA-MSW and NRSFP solutions for s the indicated values of ЕB , from [56]

1 0.8 0.6 0.4 0.2 0 0

LMA

RSFP

NRSFP

Pee

5 10 15 E [MeV]

0

5 10 15 E [MeV]

0

5 10 15 20 E [MeV]

Figure 23: Best LMA-MSW and SFP e survival probabilities from [56]

40 30

-- SNO e

2

20 10 0 10 10 10 10
-4 -3 -2 -1

10 10 10 10 2 tan

0

1

2

3

10

-4

10

-3

10

-2

10

-1

10 10 2 tan

0

1

10

2

10

3

10

4

Figure 24: 2ol versus tan2 sol , for RSFP, LMA-MSW (central minima) and NRSFP s solutions. Left and right panels refer to two different analyses described in Ref. [56].

37

statistically equivalent. However, the recent first results announced by the KamLAND collaboration [19] imply that all non-oscillation solutions are strongly disfavored. For the case of SFP solutions one finds a rejection at about 3 , similar to that of non-LMA-MSW oscillation solutions before KamLAND.

7

Neutrino Decay

It is generally agreed that most probably neutrinos have non-zero masses and non-trivial mixings. This belief is based primarily on the evidence for neutrino mixings and oscillations from the solar and atmospheric neutrino data. If neutrinos are massive they can decay. Current information on the absolute scale of neutrino mass from beta and double beta decay as well as cosmology suggests neutrino masses are at most of order of eV. Throughout the following discussion, we will stick to this assumption. In this case the only neutrino decay mo des available within the simplest versions of the SM with massive neutrinos are radiative decays of the type + and so-called invisible decays such as the three-bo dy decay 3 [34, 98] and two-bo dy decays with ma joron emmission [23]. The first one is ``visible'', while the latter two are ``invisible''. The questions are (a) whether the lifetimes are short enough to be phenomenologically interesting and (b) what are the dominant decay mo des. The answer to these is, unfortunately, rather mo del-dependent [39].

7.1

Radiative Decays

For eV neutrinos, the only radiative decay mo des possible are i j + . They can o ccur at one-lo op level in SM (Standard Mo del). The decay rate is given by [99] 9 G2 F = 1 6 1 2 8 m2j i
3 3 2

mi

Ui

Uj

m2 m2 W

(1 6 )

38

where m2j = m2 - m2 and runs over e, Е and . When mi mj , mi O (eV ) and for i i j 2 maximal mixing (4Ui2 Uj ) O (1) and ( ) one obtains for =
SM

10

-45

sec

-1

(1 7 )

which is far to o small to be interesting. The decay mo de i j + comes from an effective coupling which can be written as: e mi + mj Let us define kij as k
ij

? j Е (C + D 5 )i F

Е

(1 8 )

=

e mi + mj

| C |2 + | D |2 k0 Е

B

(1 9 )

where Е

B

= e/2me . Since the experimental bounds on Е i , the magnetic moments of

neutrinos, come from reactions such as e e e" which are not sensitive to the final state neutrinos; the bounds apply to both diagonal as well as transition magnetic moments and
i so can be used to limit k0 and the corresponding lifetimes. The current bounds are [47]:

k k
Е 0 0

e 0

< 10

-10 -10 -7

(2 0 )

< 7.4 з 10

k For mi

< 5.4 з 10

mj , the decay rate for i j + is given by = m3 k 2 2me i
2 0

(2 1 )

This, in turn, gives indirect bounds on radiative decay lifetimes for O (eV ) neutrinos of: e > 5 з 10
Е

18 16 11

sec sec sec

(2 2 )

> 5 з 10 > 2 з 10

We realize that it is the mass eigenstates which have well defined lifetimes. Converting these bounds to ones for mass eigenstates would involve factors of mixing angles squared 39

and with the large angles now indicated would change the above bounds by factors of 2 to 4 . There is one caveat in deducing these bounds. Namely, the form factors C and D are evaluated at q 2 O (eV 2 ) in the decay matrix elements whereas in the scattering from which the bounds are derived, they are evaluated at q 2 O (M eV 2 ). Thus, some justified [100].

extrapolation is necessary. It can be argued that, barring some bizarre behaviour, this is

7.2
7.2.1

Invisible Neutrino Decays
Three-body Decays

A decay mo de with essentially invisible final states which do es not involve any new particles is the three-bo dy neutrino decay mo de, i 3 . In seesaw-type extensions of the standard electroweak theory these decays are mediated by the neutral-current [98], due to the admixture of isosinglet and iso doublets [34]. As a result, in these theories there are nondiagonal couplings of the Z to the mass-eigenstate neutrinos, even at the tree level [34]. The neutral current may be expressed in the following general form
KL KL KL KH P =K K= KH KL KH KH

(2 3 )

where the matrix P = P 2 = P is directly determined in terms of the charged current lepton mixing matrix K (KL , KH ). The different entries in the P decay. The deviation of P
LL LL

sector of the P

matrix determine the neutral current couplings of the light neutrinos that induce their from the identity matrix characterizes the departure from the GIM mechanism in the neutrino sector [34, 98]. In seesaw mo dels this is expected to be tiny, for neutrino masses in the eV range. Although it can be enhanced in variant seesaw type mo dels [40, 101] where the isosinglet heavy leptons are at the weak scale instead or possibly even lighter, this decay is still likely to be negligible. Another way to induce this decay is through radiative corrections. Indeed, the i 3

decay, like the radiative mo de, can o ccur at one-lo op level in SM. With a mass pattern

40

mi

mj the decay rate can be written as
2

=

G2 m5 F j 1 9 2 3
2

(2 4 ) is given

In the SM at one-lo op level, with the internal dominating, the value of by [102]
2 SM

3 = 16
2 SM

2

m mW
-12

4

m2 n 2 mW
-35

2 (U j U i ) 2

(2 5 )

With maximal mixing

contributions; it only gives a value for of 5 з 10 bound on is quite po or:

3 з 10

. Even if

were as large as 1 with new physics sec-1 . Hence, this decay mo de will

not yield decay rates large enough to be of interest. Although the current experimental < O (100), it is still strong enough to make this mo de

phenomenologically uninteresting, at least in vacuo.

7.2.2

Two-body Decays

There is a wide variety of mo dels where neutrinos get masses due to the spontaneous violation of global lepton number symmetry, leading to a physical Nambu-Goldstone boson, called ma joron. This leads to the most well-motivated candidate for invisible two-bo dy neutrino decays [23, 39] L L + J (2 6 )

All couplings of the ma joron vanish with the neutrino masses. The structure of the ma joron coupling to mass-eigenstate neutrinos requires a careful diagonalization of the neutrino mass matrix [98]. When one performs this, typically one finds that the ma joron couling matrix has a strong tendency of being diagonal. Such GIM-like effect is a generic feature of the simplest ma joron schemes, first noted in Ref. [98]. As a result, the offdiagonal couplings of the ma joron to mass eigenstate neutrinos relevant for the neutrino decays are strongly suppressed [98], so that neutrino decays become irrelevant 5 . However, ma joron couplings are rather mo del-dependent [39], and it is possible to contrive mo dels where they are sizeable enough to lead to lifetimes of phenomenological interest (the first example in Ref. [104] is no longer phenomenologically viable, but it is possible to arrange many variants).
5

Similarly delicate is the issue of parametrizing the ma joron couplings. If one is careful, one can show

the full equivalence between polar (derivative couplings) and cartesian parametrizations [103]

41

An alternative way to generate fast invisible two-bo dy neutrino decays is in mo dels with horizontal symmetries, spontaneously broken at a scale , instead of lepton number [105]. In this case there can be several Goldstone bosons (familons), characterized by I=0, L=0, J=0. Even if there is only one familon, its coupling is typically not sub ject to the kind of cancellation characteristic of ma joron schemes, so that the new decay mo de in eq. (26) has a decay rate 1 6 2 characterized by a dimensionless coupling gp which is typically unsuppressed. =
2 gp m3

(2 7 )

In the S U (2)L symmetry limit one has a similar coupling for the charged leptons, with corresponding decay mo des becomes related to the B.R. (

+ J . Thus in this approximation the lifetime + J ) through m m
-3

= B .R.(

+ J)

(2 8 )

The current bounds on Е and branching ratios [47, 106] B .R.(Е eJ ) < 2 з 10 B .R.( ЕJ ) < 7 з 10 lead to Е > 10 > 10
24 -6 -6

(2 9 )

sec sec.

(3 0 )

20

These limits also hold for the case of an iso-doublet familon, I = 1/2, L = 0. In addition, one would need to fine tune in order to avoid mixing with the Standard Mo del Higgs. However the S U (2)L symmetry is broken, so that the above simple argument is only a very crude approximation. The strongest direct bounds on neutrino-neutrino-Goldstone couplings is that which comes from a study of pion and kaon decays [107], but these bounds allow couplings strong enough that fast decays are certainly possible. Similarly the constraint [53] which comes from 0 [108]. From now on we simply assume that fast invisible decays of neutrinos are possible, and ask ourselves whether such decay mo des can be responsible for any of the observed neutrino anomalies. 42

We assume a component of , i.e., 2 , to be the only unstable state, with a rest-frame lifetime 0 , and we assume two-flavor mixing, for simplicity: = cos2 + sin1 with m2 > m1 . From Eq. (2) with an unstable 2 , the survival probability is P

(3 1 )

= sin4 + cos4 exp(-L/E ) + 2sin2 cos2 exp(-L/2E )cos( m2 L/2E ),

(3 2 )

without oscillations there are two appropriate limits of interest. One is when the m2 is so large that the cosine term averages to 0. Then the survival probability becomes P
ЕЕ

where m2 = m2 - m2 and = m2 /0 . Since we are attempting to explain neutrino data 2 1

= sin4 + cos4 exp(-L/E )

(3 3 )

Let this be called decay scenario A. The other possibility is when m2 is so small that the cosine term is 1, leading to a survival probability of P
ЕЕ

= (sin2 + cos2 exp(-L/2E ))

2

(3 4 )

corresponding to decay scenario B. The possibility of solar neutrinos decaying to explain the discrepancy is a very old suggestion [109]. The most recent analysis of the current solar neutrino data finds that no go o d fit can be found [110]; the conclusion is valid for both the decay scenarios A as well as B. For atmospheric neutrinos, it was found that for the decay scenario A, it was not possible to obtain a go o d fit for all energies. Turning to decay scenario B, a reasonable fit was obtained for all the atmospheric data, with a minimum 2 = 33.7 (32 d.o.f.) for the choice of parameters /m = 63 km/GeV, cos2 = 0.30 The fit is of comparable quality as the one for oscillations [111]. The reason for the similarity of the results obtained in the two mo dels can be understo o d from the survival probability P (Е Е ) of muon neutrinos as a function of L/E 43 (3 5 )

for the two mo dels using the best fit parameters is very similar. In the case of the neutrino decay mo del the probability P (Е Е ) monotonically decreases from unity to an asymptotic value sin4 0.49. In the case of oscillations the probability has a sinusoidal behaviour in L/E . The two functional forms seem very different; however, taking into account the resolution in L/E , the two forms are hardly distinguishable. In fact, in the large L/E region, the oscillations are averaged out and the survival probability there can be well-approximated with 0.5 (for maximal mixing). In the region of small L/E both probabilities approach unity. In the region L/E around 400 km/GeV, where the probability for the neutrino oscillation mo del has the first minimum, the two curves are most easily distinguishable, at least in principle. It is entirely possible that the Super-K data and new analysis of this most recent decay mo del can eventually rule this out. K2K and eventually MINOS can also test this hypothesis [112]. Assuming that the neutrino oscillations provide the most likely explanation for the bulk of both atmospheric and solar neutrino observations; is it possible to place limits on the neutrino lifetimes? It is obvious that solar neutrino data will provide the strongest bounds currently possible. It has been argued convincingly by Beacom and Bell recently that under the most general assuptions the bound on the lifetime of e (or the dominant mass eigenstate components thereof ) is > 10
-4

sec for mass in the eV range [113]. The

strongest bounds can be obtained in the future from observation of MeV neutrinos from a Galactic supernova ( 105 sec) or high energy neutrinos from AGNs ( 103 sec) [114].

8
8.1

C P T and Lorentz Violation
C P T Violation in Neutrino Oscillations

Consequences of C P , T and C P T violation for neutrino oscillations have been written down before [35, 115]. We summarize them briefly for the flavor oscillation probabilities P

at a distance L from the source. If P (L) = P (L) , ??

= ,

(3 6 )

then C P is not conserved. If P (L) = P (L) , 44 = , (3 7 )

then T -invariance is violated. If P (L) = P (L) , ?? or P (L) = P (L) , ?? (3 9 ) = , (3 8 )

then C P T is violated. When neutrinos propagate in matter, matter effects give rise to apparent C P and C P T violation even if the mass matrix is C P conserving. The C P T violating terms can be Lorentz-invariance violating (LV) or Lorentz invariant. The Lorentz-invariance violating, C P T violating case has been discussed by Colladay and Kostelecky [116] and by Coleman and Glashow [117]. The effective LV C P T violating interaction for neutrinos is of the form
L b Е L , ? Е

(4 0 )

where and are flavor indices. If rotational invariance is assumed in the "preferred" frame, in which the cosmic microwave background radiation is isotropic, then the neutrino energies are eigenvalues of m2 /2p + b0 , (4 1 )

where b0 is a hermitian matrix, hereafter labeled b. In the two-flavor case the neutrino phases may be chosen such that b is real, in which case the interaction in Eq. (40) is C P T o dd. The survival probabilities for flavors and pro duced at t = 0 are given by [118] ? P (L) = 1 - sin2 2 sin2 (L/4) , and ? ? P (L) = 1 - sin2 2 sin2 (L/4) , ?? where sin 2 = ( m2 /E ) sin 2m + 2 bei sin 2b , (4 4 ) (4 5 ) cos 2 = ( m2 /E ) cos 2m + 2 b cos 2b . (4 3 ) (4 2 )

? ? and are defined by similar equations with b - b. Here m and b define the rotation angles that diagonalize m2 and b, respectively, m2 = m2 - m2 and b = b2 - b1 , 2 1 where m2 and bi are the respective eigenvalues. We use the convention that cos 2m and i cos 2b are positive and that m2 and b can have either sign. The phase in Eq. (44) is 45

the difference of the phases in the unitary matrices that diagonalize m2 and b; only one of these two phases can be absorbed by a redefinition of the neutrino states. Observable C P T -violation in the two-flavor case is a consequence of the interference of the m2 terms (which are C P T -even) and the LV terms in Eq. (40) (which are C P T -o dd); if m2 = 0 or b = 0, then there is no observable C P T -violating effect in neutrino oscillations. If m2 /E and 2 b then m and m2 /E , whereas if m2 /E 2 b then b 2 b. Hence the effective mixing angle and oscillation wavelength can vary

dramatically with E for appropriate values of b. We note that a C P T -o dd resonance for neutrinos (sin2 2 = 1) o ccurs whenever cos 2 = 0 or ( m2 /E ) cos 2m + 2 b cos 2b = 0 ; (4 6 )

similar to the resonance due to matter effects [10, 118]. The condition for antineutrinos is the same except b is replaced by - b. The resonance o ccurs for neutrinos if m2 and b have the opposite sign, and for antineutrinos if they have the same sign. A resonance can o ccur even when m and b are both small, and for all values of ; if m = b , a resonance can o ccur only if = 0. If one of or is e , then matter effects have to be included. If = 0, then = , = ( m2 /E ) + 2 b . In this case a resonance is not possible. The oscillation probabilities become P (L) = 1 - sin 2 sin P (L) = 1 - sin2 2 sin ??
2 2

(4 7 ) (4 8 )

2

m2 b + L, 4E 2 m2 b L. - 4E 2

(4 9 ) (5 0 )

For fixed E , the b terms act as a phase shift in the oscillation argument; for fixed L, the b terms act as a mo dification of the oscillation wavelength. An approximate direct limit on b when = Е can be obtained by noting that in atmospheric neutrino data the flux of downward going Е is not depleted, whereas that of upward going Е is depleted [12]. Hence, the oscillation arguments in Eqs. (49) and (50) cannot have fully developed for to the upper bound | b| < 3 з 10 downward neutrinos. Taking | bL/2| < /2 with L 20 km for downward events leads
-20

GeV; the K2K results can improve this by an order of 46

magnitude; upward going events could in principle test | b| as low as 5 з 10

-23

GeV. Since

the C P T -o dd oscillation argument depends on L and the ordinary oscillation argument on L/E , improved direct limits could be obtained by a dedicated study of the energy and zenith angle dependence of the atmospheric neutrino data. The difference between P

and P

??

P (L) - P (L) = -2 sin2 2 sin ??

m2 L sin( bL) , 2E

(5 1 )

can be used to test for C P T -violation. In a neutrino factory, the ratio of Е Е to ? ? Е Е events will differ from the Standard Mo del (or any lo cal quantum field theory mo del) value if C P T is violated. A 10kT detector, with 1019 stored muons, can probe
-23

b to a level of 3.10

GeV [119]. Combining KamLAND and solar neutrino data would

probe b to similar levels. Lorentz invariant C P T violation can arise if e.g. m2j and ij i are different for neutrinos and antineutrinos. Constraints on such differences are rather weak [118]. Taking advantage of this, a very intriguing proposal has been made by several authors [120]. It was proposed that in the sector, the m2 and mixing are "conventional" and nearly bimaximal; namely m23 and m21 lie in the atmospheric range determined in 2 2 Sec. 3.2 and in the LMA-MSW region determined in Secs. 3.1, respectively. In contrast, in the sector m23 0(eV 2 ), m21 lies in the atmospheric range and the mixing is large ? 2 2 in the 1-2 sector but small (of order LSND) in 2-3 sector. Then the Е - e conversion in ?? LSND [14] is accounted for, and the solar neutrinos are unaffected as no s are emitted ? in the sun. This proposal can be tested by Mini-Bo one seeing LSND effect in Е beam, ? but not in the Е beam, and by the fact that the e and e oscillations with m2tm will ? a be very different (present in former and absent in latter). For example, KamLAND [121] will see no effect in reactor e s even if LMA-MSW is the correct solution for solar e s. ? This is of course at o dds with the KamLAND confirmation of the LMA-MSW solution. At neutrino factories, (fractional) C P T violating mass differences and mixing parameters can be probed to a percent level [119]. It should be stressed that mo dels which have different masses for particles and anti-particles only seem Lorentz invariant (and nonlo cal); however, the neutrino propagators will also violate Lorentz invariance and so they are actually Lorentz non-invariant as well [122]. After the announcement of KamLAND results, which are in general agreement with the expectations from LMA-MSW and hence C P T conservation; a mo dified C P T -violating 47

scenario to account for LSND has been proposed [123]. The idea is that in the antineutrino sector, instead of the LSND and the atmospheric splittings, now there are the LSND and the KamLAND splittings. At the moment it seems possible to fit the atmospheric data. The solar mass difference and the KamLAND mass differences need not be the same, hence LMA-MSW is not yet established according to the authors.

8.2

Lorentz Invariance Violation in Neutrino Oscillations

A general formalism to describe small departures from exact Lorentz invariance has been developed by Colladay and Kostelecky [124]. This mo dification of Standard Mo del is renormalizable and preserves the gauge symmetries. When rotational invariance in a preferred frame is imposed, the formalism developed by Coleman and Glashow [125] can be used. In this form, the main effect (at high energies) of the violation of Lorentz invariance is that each particle species i has its own maximum attainable velo city (MAV), ci , in this frame. The Lorentz violating parameters are c2 - c2 . There are many interesting i j consequences [125]: evading of GZK cut-off, possibility of "forbidden" pro cesses at high thresholds e.g. e+ + e- , p e+ + n + , Е + Е , Е e + etc. Moreover, even eigenstates and the flavor survival probability (in the two flavor case) is given by P

if neutrinos were massless, the flavor eigenstates could be mixtures of velo city (MAV)

= 1 - sin2 2 sin

2

c LE 2

(5 2 )

where c = c1 - c2 . Identical phenomenology for neutrino oscillations arises in the case placing c. Here is the gravitational potential and = 1 - 2 is the difference in

of flavor violating gravity or the violation of equivalence principle (VEP), with rethe post-Newtonian parameters used to test General Relativity [126] and which break the

equivalence principle. This mechanism was first proposed by Gasperini and by Halprin and Leung [127, 128]. It provides a different realization of the phenomenon of oscillation amongst massless neutrinos, first proposed in Ref. [41] in the context of neutrino non-standard interactions, as discussed in Sec. 5. There are, however, some important theoretical differences between the two proposals. There do es not seem to be a consistent theoretical scheme for VEP, since no theory of gravity obeying the classic General Relativity tests and also violating the equivalence principle has ever been found [129]. In contrast 48

the resonant oscillation of massless neutrinos due to NSI has a well-defined theoretical basis, either in terms of effective neutrino non-orthonomality, or due to the existence of new particles coupled to neutrinos [41, 77]. The VEP form of massless neutrino oscillations was very interesting at one time. The reason was that a single choice of parameters c and sin2 2 could account for both atmospheric and solar neutrinos with e - Е mixing [130]. dependence is ruled out for atmospheric neutrinos [131], except as a sub-leading effect. A with the choice of parameters: c/2 10
-24

However, now Е - e can no longer account for atmospheric neutrinos [54] and the LE description of solar neutrinos, even including the recent SNO data, is still possible [132]; and large mixing. However, this is ruled out to the extent that KamLAND confirms the LMA-MSW solution for solar neutrinos; and hence must be a sub-leading effect. For Е - x mixing, the results of CCFR [133] can be used to constrain c/2 < 10
-21

(for sin2 2 > 10-3 ), and future Long Baseline
23

experiments [134] will extend the bounds to 10-

for large mixing. In the general case,

when neutrinos are not massless, the energies are given by Ei = p + m2 /2p + ci p i (5 3 )

There will be two mixing angles (even for two flavors) and the survival probability is given by P where sin 2 = | ( m2 /E ) sin 2m + 2 cei E sin 2c |, cos 2 = ( m2 /E ) cos 2m + 2 c E cos 2c (5 5 ) (5 6 )

= 1 - sin2 2 sin2 (L/4)

(5 4 )

One can also write the most general expression including the C P T violating term of Eq. (6) and even extending to three flavors. But there is not enough information to constraint the many new parameters. When data from Long Baseline experiments and eventually neutrino factories become available, C P T and Lorentz violation in neutrino oscillations can be probed to new and significant levels. It would be especially useful to have detectors capable of distinguishing between and events. ?

49

9
9.1

Neutrino Physics with Future Exp eriments
Probing Spin Flavor Precession with Borexino

Irrespective of KamLAND, future data from the upcoming Borexino experiment will be useful in distinguishing the LMA-MSW solution from the spin flavor precession solutions described above in Sec. 6. Indeed, the Borexino experiment has the potential to distinguish both the NRSFP solution and the simplest RSFP solution with no mixing [56, 135] from the LMA-MSW solution, as summarized in Fig. 25. See Ref. [56] for more details. On the other hand a strong confirmation of the LMA-MSW oscillation solution

Figure 25: Predicted RB from [56]

orexino

values for LMA-MSW and spin flavor precession solutions,

by KamLAND [136] would imply that spin-flavor-precession may at best be present at a sub-leading level, leading to a constraint on ЕB . Note that, if neutrino transition neutrino magnetic moments exist, then neutrino conversions within the Sun result will result in partial polarization of the initial solar neutrino fluxes. This opens a new opportunity to observe the electron antineutrinos [137]. By measuring the slopes of the energy dependence of the differential neutrino electron scattering cross section one can show how e e conversions may take place for low energy so? lar neutrinos in the Borexino region, while being unobservable at the Kamiokande and Super-Kamiokande experiments.

50

9.2

Probing Spin Flavor Precession with KamLAND

Accepting the LMA-MSW solution to the solar neutrino anomaly, as indicated by first KamLAND results, one can still probe the admixture of alternative mechanisms of solar neutrino conversion, such as Spin Flavor Precession. In fact we argue that this will be an interesting ob ject of study. With sufficient statistics it should be possible to constrain such sub-leading admixtures, as discussed in [56]. As an illustration, one can place a constraint on ЕB (here B is the maximum transverse solar magnetic field at the convective zone) by searching for a solar anti-neutrino flux, expected in the SFP scenarios. This constraint will depend on how go o d is the KamLAND determination of the LMA-MSW oscillation parameters, as illustrated in Fig. 26. In this Figure we have displayed the electron anti1 m2=210-5eV2 m2=510-5eV2 m2=10-4eV2

-- /8 [%]

0.8 0.6 0.4 0.2 0 0

e

B

0.5 1 1.5 0 0.5 1 1.5 2 2.5 3 0 0.5 1 1.5 2 2.5 3 Е11Bmax [MG] Е11Bmax [MG] Е11Bmax [MG]

Figure 26: KamLAND sensitivity on the Ma jorana neutrino transition magnetic moment for the case of the LMA-MSW solution. See text. neutrino flux predicted at KamLAND (E > 8.3 MeV) for three different m2ol values s (indicated in the figure) and for tan2 sol values varying in the range from 0.3-0.8, as a function of Е11 Bmax , Е and Bm
ax 11

being the magnetic moment in units of 10-

11

Bohr magneton

being the maximum magnetic field in the convective zone. The extremes of the

neutrino mixing range correspond to the solid and dashed lines indicated in the figure, while the horizontal line corresponds to a KamLAND sensitivity on the anti-neutrino flux of 0.1 %, expected with three years running [136]. Clearly the limits on the transition magnetic moments are sensitive also to the ultimate central m2ol value indicated by s KamLAND, being more stringent for lower m2ol values, as seen from the left panel. A s 10 % error on m2ol is aimed at by the collaboration. s

51

9.3

Constraining Neutrino Magnetic Moments with Borexino

Solar neutrino data can also be used to derive stringent bounds on Ma jorana neutrino transition magnetic moments Еij [92, 138], irrespective of the value of the solar magnetic field. As discussed in Ref. [139] accepting that LMA-MSW accounts for the solar neutrino data, one can still probe Ma jorana neutrino transition magnetic moments: if present they would contribute to the neutrino-electron scattering cross section and hence affect the signal observed in Super-Kamiokande. Assuming that LMA-MSW is the solution of the solar neutrino problem Ref. [139] constrains neutrino TMs by using the latest global solar neutrino data. One finds that all elements of the TM matrix can be bounded at the same time. Moreover, Ref. [139] shown how reactor data play a complementary role to the solar neutrino data. The resulting combined solar plus reactor bound on TMs is 2 з 10
-10

ЕB at the 90% C.L.

Contours of the 90% C.L. bound on the magnitude of the Ma jorana neutrino magnetic moments after 3 years of Borexino data-taking, in units of 10-10 ЕB are displayed in Fig. 27. In this figure the current best fit point is denoted by the star, and the shaded region is
10
-3

0.55

0.5
0.45

m [eV ]

2

0.4 0.35

2

10

-4

0.3

#

0.27 0.245

0.245
0.27
0.3
0.35 0.4
1

10 0.1

-5

tan

2

Figure 27: Contours of the 90% C.L. bound on the magnitude of the Ma jorana neutrino magnetic moments after 3 years of Borexino data-taking, in units of 10 at 3 , from first paper in Ref. [139]. the allowed 3 LMA-MSW region obtained in the first paper in Ref. [139], where details of the analysis can be found. One sees that, thanks to the lower energy, the sensitivity 52
-10

ЕB . The current

best fit point is shown by the star, and the shaded region is the allowed LMA-MSW region

of the upcoming Borexino experiment is about an order of magnitude better than that of current solar neutrino data. Given the relative delay in the start of the Borexino experiment, probing neutrino magnetic moments constitutes one of its most interesting physics goals, as no other current experiment can probe TMs with comparable sensitivity. Another interesting item for Borexino is to test for Non-Standard neutrino interactions. This possibility has been recently discussed in Ref. [140].

9.4

Constraining New Gauge Bosons at Very Low Energies

Some electroweak mo dels with extended neutral currents, such as those based on the typically below 100 keV [141]. It has been suggested in that the search for the effects of a heavy Z' gauge boson contribution would be feasible in an experiment with a highactivity artificial neutrino source and a large-mass detector. The neutrino flux is known to within a percent accuracy and, in contrast to the reactor neutrino case, one can reach lower neutrino energies. Both features make the proposed experiment more sensitive to extended gauge mo dels, such as the mo del [39]. In Fig. 28 we briefly summarize the results obtained in Ref. [142] for the case for the proposed LAMA experiment, with a large NaI(Tl) detector lo cated at the Gran Sasso underground laboratory. One sees that,
0
600

E6 group [39], lead to an increase of the - e scattering cross section at low energies, ?

-0.002

400

-0.004

-0.006
200

-0.008

0

0

1

2

3

syst (%)

4

-0.01

0

1

2

3

syst

(%)

4

Figure 28: Attainable 95 % C. L. sensitivity to the mass (left panel) and mixing (right) of an extra gauge boson in the mo del, plotted versus the systematic error per bin. The results correspond to the cases of a 400 kg (solid line) and 1-ton detector (dashed line). for a low enough background, the sensitivity to the Z boson mass would reach 600 GeV for one year running of the experiment. These values are reasonably competitive, and in 53

any case complementary, to the sensitivity from direct searches at the Tevatron [143], or through precision electroweak tests [144].

9.5

Probing Non-Standard Interactions at Neutrino Factories

The primary goal of neutrino factories is to probe the lepton mixing angle 13 with much better sensitivity than possible at present and, hopefully, also the possibility of leptonic C P violation [145, 146]. We have already discussed both the hierarchical nature of neutrino of mass splittings indicated by the observed solar and atmospheric neutrino anomalies, as well as the stringent bound on 13 that follows from reactor experiments Cho oz and Palo Verde. We also mentioned in Sec. 2.1 that the leptonic C P violation asso ciated to the standard Dirac phase present in the simplest three-neutrino system (charcterized by a unitary CC mixing matrix) disappears as two neutrinos become degenerate and/or as 13 0 [37]. As a result, although the large mixing indicated by current solar neutrino a very demanding task for neutrino factories. Here we emphasise on the role of neutrino factories in probing non-standard interactions. It has been shown [147] that NSI in the Е - channel can be studied with substantially improved sensitivity in the case of flavor changing NSI, especially at energies higher than approximately 50 GeV, as illustrated in Fig. 29. For example, a 100 GeV Nufact can probe FC-NSI interactions at the level of | | < few з 10
10
1

data certainly helps, direct leptonic C P violation tests in oscillation experiments will be

-4

at 99 % C.L.

E

20 GeV 10
m m 0 0

1

E

50 GeV
m m 0 0

10

0

10

0

'

10

1

' 10
1

10

2

10 10
4

2

10

3

10

2

10

1

10

4

10

3

10

2

10

1

Figure 29: Comparing the sensitivity to neutrino NSI of current atmospheric neutrino experiments (white) with future neutrino factory experiments (grey), details in Ref. [147]

54

Note also that in such hybrid solution to the neutrino anomalies, with FC-NSI explaining the solar data, and oscillations accounting for the atmospheric data, the two sectors are connected not only by the neutrino mixing angle 13 , but also by the e - flavor changing NSI parameters. As a result NSI and oscillations may be confused, as shown in [148]. This implies that information on 13 can only be obtained if bounds on NSI are available. Taking into account the existing bounds on FC interactions, one finds a drastic loss in Nufact sensitivities on 13 , of at least two orders of magnitude, as illustrated in Fig. 30
10
1

a c

d e 10
2

b

10

3

10

4

10

3

10 sin2 213

2

10

1

Figure 30: 99% C.L. allowed regions (black lines) in sin2 213 - displayed in grey. Details in Ref. [148]

e

for different input values,

as indicated by the points, at a baseline of 3 000 km. Lines of constant event rates are

A near-detector offers the possibility to obtain stringent bounds on some NSI parameters and therefore constitutes a crucial necessary step towards the determination of 13 and subsequent study of leptonic C P violation.

10

Discussion and Outlook

These are exciting times for neutrino physics, driven mainly by experiment. We have given a brief overview on the status of neutrino oscillation physics, including the determination of mass splittings and mixings from current data. Recent results bring substantial expectation on the potential of future data both of KamLAND and K2K which provide

55

independent tests of the solar and atmospheric neutrino anomalies from terrestrial, mancontrolled neutrino sources. The solar neutrino m2ol will be better determined after 3 s years of KamLAND running, especially if the solar data also improve in the meantime. Unfortunately progress in the determination of the solar angle will be less impressive. In contrast to the Cabibbo angle, the mixing between the first two generations of leptons has been shown to be large, though significantly non-maximal. This opens new ways to probe the solar interior as well as supernovae. KamLAND has brought a turning point to the possibility of non-oscillation descriptions of the solar neutrino data, such as those invoking spin-flavor precession or nonstandard neutrino interactions. Although such descriptions currently provide an excellent fit of the solar data, they are now globally disfavored by about 3 and can only play a sub-leading role in the solar neutrino anomaly. Analysing in further detail the resulting constraints is beyond the scope of this short review, which was commissioned well-before these results were available. Accepting the LMA-MSW solution, we have nevertheless illustrated how current and future neutrino data can place important restrictions on non-standard neutrino properties, such as magnetic moments. We have also discussed the potential in constraining non-standard neutrino properties of future data from experiments such as KamLAND, Borexino and the upcoming neutrino factories. We have also considered how solar and atmospheric neutrino data can be used to place constraints on neutrino instability, as well as C P T and Lorentz Violation. Let us stress that interest still persists in the investigation of non-standard neutrino properties, to the extent that, at least some, are well-motivated by theory. Last, but not least, non-oscillation phenomena such as neutrinoless double beta decay would, if discovered, probe the absolute scale of neutrino mass and also reveal their Ma jorana nature. With the era of neutrino properties entering a new age, we can only hope that the underlying mechanism for generating neutrino mass will start revealing its nature, a formidable task indeed.

56

Acknowledgements
This work was supported in part by Spanish grant BFM2002-00345, by the European Commission RTN grant HPRN-CT-2000-00148, by the ESF Neutrino Astrophysics Network, and by the U.S. D.O.E. under grant DE-FG03-91ER40833. We thank all our collaborators, for the physics and for the fun, especially those directly involved on the analysis of recent neutrino data. Special thanks also to Michele Maltoni and Timur Rashba, for technical help, to Sergio Pastor and Georg Raffelt for discussions on Sec. 4, and to Mariam Tortola for pro of-reading. One of us (S.P.) would like to thank the Theory group at KEK for their hospitality while this work was carried out.

References
[1] B. T. Cleveland et al., "Measurement of the Solar Electron Neutrino Flux with the Homestake Chlorine Detector," Astrophys. J. 496, 505 (1998). [2] W. Hampel et al. [GALLEX Collaboration], "GALLEX solar neutrino observations:...," Phys. Lett. B 447, 127 (1999). [3] J. N. Abdurashitov et al. [SAGE Collaboration], "Measurement of the solar neutrino capture rate by SAGE...," Phys. Rev. Lett. 83, 4686 (1999); Phys. Rev. C 60, 055801 (1999); J. Exp. Theor. Phys. 95, 181 (2002) [Zh. Eksp. Teor. Fiz. 122, 211 (2002)] [4] M. Altmann et al. [GNO Collaboration], "GNO solar neutrino observations...," Phys. Lett. B 490, 16 (2000); E. Bellotti, Nucl. Phys. Proc. Suppl. 91, 44 (2001). [5] S. Fukuda et al. [Super-K Collaboration], "Determination of solar neutrino oscillation parameters using 1496 days...," Phys. Lett. B 539, 179 (2002) and references therein [6] Q. R. Ahmad et al. [SNO Collaboration], "Direct evidence for neutrino flavor transformation from neutral-current ...; Phys. Rev. Lett. 89, 011301 (2002), and "Measurement of day and night neutrino energy spectra at SNO..." Phys. Rev. Lett. 89, 011302 (2002) [7] Q. R. Ahmad et al. [SNO Collaboration], "Measurement of the charged current interactions produced by B-8 solar neutrinos...," Phys. Rev. Lett. 87, 071301 (2001) [8] J. Bahcall, Int. Conf. on Neutrino Physics and Astrophysics, Munich 2002; B. Ricci, V. Berezinsky, S. Degl'Innocenti, W. A. Dziembowski, G. Fiorentini, "Helioseismic constraints to the central solar temperature and neutrino fluxes," Phys. Lett. B 407 (1997) 155 [9] M. Maltoni, T. Schwetz, M. A. Tortola and J. W. Valle, "Constraining neutrino oscillation parameters with current solar and atmospheric data," Phys. Rev. D 67 013011 (2003), [arXiv:hep-ph/0207227]. This paper gives an extensive list of earlier references on solar neutrino data analyses [10] L. Wolfenstein, "Neutrino Oscillations In Matter," Phys. Rev. D 17, 2369 (1978); S. P. Mikheev and A. Y. Smirnov, "Resonance Enhancement of Oscillations...," Sov. J. Nucl. Phys. 42 (1985) 913

57

[11] M. C. Gonzalez-Garcia et al, "Status of the MSW solutions of the solar neutrino problem," Nucl. Phys. B 573, 3 (2000); J. N. Bahcall, P. I. Krastev, A. Y. Smirnov, Phys. Rev. D 60 (1999) 093000 [12] Y. Fukuda et al., Kamiokande Coll., Phys. Lett. B 335 (1994) 237; R. Becker-Szendy et al., IMB Coll., Nucl. Phys. B (Proc. Suppl.) 38 (1995) 331; W.W.M. Allison et al., Soudan Coll., Phys. Lett. B 449 (1999) 137. Super-Kamiokande Coll., Y. Fukuda et al., Phys. Rev. Lett. 81 (1998) 1562 and 82 (1999) 2644; C. McGrew in Neutrino Telescopes 2001, Venice, Italy, March 2001; T. Toshito in Moriond 2001, Les Arcs, France, March 2001. MACRO Coll., M. Ambrosio et al., Phys. Lett. B 434 (1998) 451; M. Spurio et al., hep-ex/0101019; B. Barish, Proc. of Neutrino 2000, http://nu2000.sno.laurentian.ca}. A. Surdo, Talk given at TAUP 2001, 8-12 September 2001, Gran Sasso, Italy (http://www.lngs.infn.it/ ). [13] G. Battistoni et al "Progresses in the validation of the FLUKA atmospheric nu flux calculations," Nucl. Phys. Proc. Suppl. 110 (2002) 336 [14] A. Aguilar et al. [LSND Collaboration], "Evidence for neutrino oscillations..." Phys. Rev. D 64, 112007 (2001) See also talk by G. Drexlin, at International Conference on Neutrino Physics and Astrophysics, http://neutrino2002.ph.tum.de/pages/transparencies2.html [15] Y. Declais et al., "Search for neutrino oscillations... from a nuclear power reactor at Bugey," Nucl. Phys. B 434 (1995) 503. [16] F. Dydak et al., "A Search For Muon-Neutrino Oscillations...," Phys. Lett. B 134 (1984) 281. [17] B. Armbruster et al. [KARMEN Collaboration], "Upper limits for neutrino oscillations Е e ? ? ....," Phys. Rev. D 65 (2002) 112001 [18] M. Apollonio et al. [CHOOZ Collaboration], "Limits on neutrino oscillations from the CHOOZ experiment," Phys. Lett. B 466 (1999) 415; F. Boehm et al, [Palo Verde Coll], "Final results from the Palo Verde...," Phys. Rev. D 64 (2001) 112001 [19] K. Eguchi et al [KamLAND Collaboration], "First results from KamLAND: Evidence for reactor anti-neutrino disappearance," hep-ex/0212021. [20] M. H. Ahn et al. [K2K Collaboration], "Indications of neutrino oscillation in a 250-km long-baseline experiment," hep-ex/0212007. [21] M. Gell-Mann, P. Ramond and R. Slansky in Supergravity (North Holland, Amsterdam 1979); T. Yanagida in Proc. of the Workshop on Unified Theory and Baryon Number of the Universe, KEK, Japan, 1979. [22] R. N. Mohapatra and G. Senjanovic, "Neutrino Mass And Spontaneous Parity Nonconservation," Phys. Rev. Lett. 44 (1980) 912; J. Schechter and J. W. F. Valle, "Neutrino Masses in SU(2) U(1) Theories," Phys. Rev. D 22, 2227 (1980) [23] Y. Chikashige, R. N. Mohapatra and R. D. Peccei, "Are there Real Goldstone Bosons ...?," Phys. Lett. B 98 (1981) 265; J. Schechter and J. W. F. Valle, "Neutrino Decay And Spontaneous Violation Of Lepton Number," Phys. Rev. D 25 (1982) 774; G. B. Gelmini and J. W. F. Valle, "Fast Invisible Neutrino Decays," Phys. Lett. B 142, 181 (1984). [24] S. Weinberg, "Opening Address, Neutrinos 78" Proc., West Lafayette 1978, 1; R. Barbieri, J. R. Ellis and M. K. Gaillard, "Neutrino Masses and Oscillations in SU(5)," Phys. Lett. B 90, 249 (1980). [25] A. Zee, "A Theory Of Lepton Number Violation...," Phys. Lett. B 93 (1980) 389 [Err-ibid. B 95 (1980) 461]; K. S. Babu, "Model Of 'Calculable'...," Phys. Lett. B 203 (1988) 132.

58

[26] A. Masiero and J. W. Valle, "A Model For Spontaneous (1990) 273; J. C. Romao et al, "How To Spontaneously Br 311; J. C. Romao and J. W. Valle, "Neutrino Masses In (1992) 87. For early, pre-LEP papers, see C. S. Aulakh, R. 13; G. G. Ross, J. W. F. Valle, Phys. Lett. B 151 (1985) (1985) 142; A. Santamaria, J. W. F. Valle, Phys. Lett. B 1 (1988); Phys. Rev. D 39, 1780 (1989).

R Parity Breaking," Phys. Lett. B 251 eak R-Parity," Phys. Lett. B 288 (1992) Supersymmetry...," Nucl. Phys. B 381 N. Mohapatra, Phys. Lett. B 119 (1982) 375; J. R. Ellis et al, Phys. Lett. B 150 95, 423 (1987); Phys. Rev. Lett. 60, 397

[27] M. A. Diaz et al, "Minimal supergravity with R-parity breaking," Nucl. Phys. B 524 (1998) 23; M. Hirsch et al, "Neutrino masses and mixings from supersymmetry..." Phys. Rev. D 62 (2000) 113008 [Err-ibid. D 65 (2002) 119901] and references therein. [28] M. Hirsch et al, "Probing neutrino properties with charged scalar lepton decays," Phys. Rev. D 66 (2002) 095006; W. Porod et al, "Testing neutrino mixing at future collider experiments," Phys. Rev. D 63 (2001) 115004; D. Restrepo, W. Porod and J. W. Valle, "Broken R-parity, stop decays, and neutrino physics," Phys. Rev. D 64 (2001) 055011; S. Y. Choi, E. J. Chun, S. K. Kang and J. S. Lee, "Neutrino oscillations and R-parity... signals," Phys. Rev. D 60 (1999) 075002; J. C. Romao et al, "A supersymmetric solution...," Phys. Rev. D 61, 071703 (2000) B. Mukhopadhyaya, S. Roy and F. Vissani, "Correlation between neutrino oscillations...," Phys. Lett. B 443 (1998) 191 [29] A. Ioannisian and J. W. Valle, "SO(10) grand unification model for degenerate neutrino masses," Phys. Lett. B 332 (1994) 93; D. O. Caldwell and R. N. Mohapatra, "Neutrino Mass Explanations Of Solar And Atmospheric Neutrino Deficits And Hot Dark Matter," Phys. Rev. D 48 (1993) 325 [30] K. S. Babu, E. Ma and J. W. F. Valle, "Underlying A(4) symmetry for the neutrino mass matrix and the quark mixing matrix," Phys. Lett. B 552 (2003) 207 [hep-ph/0206292] [31] See, e. g. P. H. Chankowski et al, "Neutrino unification," Phys. Rev. Lett. 86 (2001) 3488 [hep-ph/0011150] [32] S. Davidson and S. F. King, "Bi-maximal neutrino mixing in the MSSM with a single right-handed neutrino," Phys. Lett. B 445 (1998) 191; Q. Shafi and Z. Tavartkiladze, "Bi-maximal neutrino mixings and proton decay in SO(10)...," Phys. Lett. B 487 (2000) 145 K. S. Babu and R. N. Mohapatra, "Predictive schemes for bimaximal neutrino mixings," Phys. Lett. B 532 (2002) 77. [33] For reviews see, e. g. G. Altarelli and F. Feruglio, "Neutrino Masses And Mixings: A Theoretical Perspective," Phys. Rept. 320 (1999) 29; S. M. Barr and I. Dorsner, "A general classification of three neutrino models...," Nucl. Phys. B 585 (2000) 79; G. G. Ross and L. Velasco-Sevilla, "Symmetries and fermion masses," hep-ph/0208218, and S. King talk at Neutrino 2002. [34] J. Schechter and J. W. F. Valle, "Neutrino Masses in SU(2) U(1) Theories," Phys. Rev. D 22 (1980) 2227. [35] J. Schechter and J. W. F. Valle, "Neutrino Oscillation Thought Experiment," Phys. Rev. D 23 (1981) 1666. [36] M. Doi, T. Kotani, H. Nishiura, K. Okuda and E. Takasugi, "CP Violation in Ma jorana Neutrinos," Phys. Lett. B 102 (1981) 323. For a recent review see S. M. Bilenky, C. Giunti and W. Grimus, "Phenomenology of neutrino oscillations," Prog. Part. Nucl. Phys. 43 (1999) 10 [37] J. Schechter, J. W. F. Valle, "Comment on The Lepton Mixing Matrix" Phys. Rev. D 21 (1980) 309 [38] G. C. Branco et al, "Leptonic CP Violation with Massless Neutrinos," Phys. 385; N. Rius, J. W. F. Valle, "Leptonic CP Violating Asymmetries...," Phys. 249; M. C. Gonzalez-Garcia and J. W. F. Valle, "Enhanced lepton flavor vio neutrinos...," Mod. Phys. Lett. A 7 (1992) 477; A. Ilakovac, A. Pilaftsis, Nucl. 491; J. Bernabeu et al, Phys. Lett. B 187 (1987) 303. Lett. Lett. lation Phys. B 225 (1989) B 246 (1990) with massless B 437 (1995)

59

[39] For a review see J. W. F. Valle, "Gauge Theories And The Physics of Neutrino Mass," Prog. Part. Nucl. Phys. 26, 91 (1991). [40] R. N. Mohapatra and J. W. F. Valle, "Neutrino Mass And Baryon-Number Nonconservation In Superstring Models," Phys. Rev. D 34 (1986) 1642. [41] J. W. F. Valle, "Resonant Oscillations of Massless Neutrinos In Matter," Phys. Lett. B 199, 432 (1987). [42] J. T. Peltoniemi, D. Tommasini and J. W. F. Valle, "Reconciling dark matter and solar neutrinos," Phys. Lett. B 298, 383 (1993); J. T. Peltoniemi and J. W. F. Valle, "Reconciling dark matter, solar and atmospheric neutrinos," Nucl. Phys. B 406, 409 (1993); Caldwell & Mohapatra in [29] Giunti and Lavader's excellent web-page http://www.to.infn.itgiunti/neutrino/ [43] M. Maltoni, T. Schwetz and J. W. F. Valle, "Status of four-neutrino mass schemes: A global and unified approach to current neutrino oscillation data," Phys. Rev. D 65, 093004 (2002) [hep-ph 0112103] [44] M. Maltoni, T. Schwetz, M. A. Tortola and J. W. F. Valle, "Ruling out four-neutrino oscillation interpretations of the LSND anomaly?," Nucl. Phys. B 643 (2002) 321 [hep-ph/0207157] [45] A. Osipowicz et al. [KATRIN Coll], "Katrin: A next generation tritium beta decay experiment with sub-eV sensitivity for the electron neutrino mass," hep-ex/0109033 and references therein [46] O. Elgaroy et al, "A new limit on the total neutrino mass from the 2dF galaxy redshift survey," astro-ph/0204152. For a theoretical discussion see S. Hannestad, astro-ph/0211106. [47] K. Hagiwara et al. "Review Of Particle Physics," Phys. Rev. D 66 (2002) 010001 [48] For reviews on double beta decay experiments and nuclear theory see, A. Morales, Nucl. Phys. Proc. Suppl. 77, 335 (1999); P. Vogel, nucl-th/0005020; A. Faessler and F. Simkovic, Prog. Part. Nucl. Phys. 46 (2001) 233; M. Doi, T. Kotani and E. Takasugi, "Double Beta Decay And Ma jorana Neutrino," Prog. Theor. Phys. Suppl. 83, 1 (1985). [49] J. Schechter and J. W. F. Valle, "Neutrinoless Double-Beta Decay In SU(2) X U(1) Theories," Phys. Rev. D 25, 2951 (1982). [50] L. Wolfenstein, "Different Varieties Of Massive Dirac Neutrinos," Nucl. Phys. B 186 (1981) 147; J. W. F. Valle and M. Singer, "Lepton Number Violation with Quasi Dirac Neutrinos," Phys. Rev. D 28, 540 (1983). [51] J. W. F. Valle, "Neutrinoless Double-Beta Decay with Quasi-Dirac Neutrinos," Phys. Rev. D 27, 1672 (1983). [52] V. Barger, S. L. Glashow, D. Marfatia, K. Whisnant, "Neutrinoless double beta decay can constrain neutrino dark matter," Phys. Lett. B 532 (2002) 15; F. Feruglio, A. Strumia, F. Vissani, "Neutrino oscillations and signals in beta and 0nu 2beta experiments," Nucl. Phys. B 637 (2002) 345; H. Minakata, H. Sugiyama, "Constraints on neutrino mixing parameters by observation of neutrinoless double beta decay," Phys. Lett. B 532, 275 (2002) [53] H. V. Klapdor-Kleingrothaus et al. [GENIUS Collaboration], "GENIUS: A supersensitive germanium detector system for rare events," hep-ph/9910205; E. Fiorini, "Cuore: A Cryogenic Underground Observatory For Rare Events," Phys. Rept. 307, 309 (1998); A. Bettini, "Neutrino Physics At Gran Sasso Laboratory," Nucl. Phys. Proc. Suppl. 100, 332 (2001). [54] M. C. Gonzalez-Garcia et al, "Global three-neutrino oscillation analysis of neutrino data," Phys. Rev. D 63, 033005 (2001) [hep-ph/0009350].

60

[55] Talk by E. Lisi at XXth International Conference on Neutrino Physics and Astrophysics, http://neutrino2002.ph.tum.de/pages/transparencies2.html and references therein [56] J. Barranco et al, "Confronting spin flavor solutions of the solar neutrino problem with current and future solar neutrino data," Phys. Rev. D 66 (2002) 093009 [hep-ph/0207326]. [57] N. Fornengo et al, "Probing neutrino non-standard interactions with atmospheric neutrino data," Phys. Rev. D 65, 013010 (2002) [hep-ph/0108043]. [58] N. Fornengo et al, "Updated global analysis of the atmospheric neutrino data in terms of neutrino oscillations," Nucl. Phys. B 580, 58 (2000) [hep-ph/0002147]. [59] M. Maltoni, T. Schwetz and J. W. F. Valle, "Combining first KamLAND results with solar neutrino data," hep-ph/0212129. [60] P. Vogel and J. Engel, "Neutrino Electromagnetic Form-Factors," Phys. Rev. D 39, 3378 (1989). [61] H. Murayama and A. Pierce, "Energy spectra of reactor neutrinos at KamLAND," Phys. Rev. D 65, 013012 (2002) [62] The KamLAND proposal, Stanford-HEP-98-03; A. Piepke, talk at Neutrino-2000, XIXth International Conference on Neutrino Physics and Astrophysics, Sudbury, Canada, June 2000. [63] P. Vogel and J. F. Beacom, "The angular distribution of the reaction e + p e+ + n," Phys. Rev. ? D 60, 053003 (1999) [64] E. D. Church, K. Eitel, G. B. Mills and M. Steidl, "Statistical analysis of different Е e ? ? searches," Phys. Rev. D 66 (2002) 013001 [65] P. C. de Holanda, A. Smirnov, hep-ph/0212270; P. Aliani et al, hep-ph/0212212; H. Nunokawa, W. J. Teves, R. Z. Funchal, hep-ph/0212202; J. N. Bahcall, M. C. Gonzalez-Garcia, C. PenaGaray, hep-ph/0212147; A. Bandyopadhyay, S. Choubey, R. Gandhi, S. Goswami, D. P. Roy, hep-ph/0212146; G. L. Fogli, E. Lisi, A. Marrone, D. Montanino, A. Palazzo, A. M. Rotunno, hep-ph/0212127; V. Barger, D. Marfatia, hep-ph/0212126; H. Minakata, H. Sugiyama, hep-ph/0212240. [66] A. de Gouvea and C. Pena-Garay, "Solving the solar neutrino...," Phys. Rev. D 64, 113011 (2001) [67] V. D. Barger, D. Marfatia and B. P. Wood, "Resolving the solar neutrino problem with KamLAND," Phys. Lett. B 498, 53 (2001) [68] A. D. Dolgov, "Neutrinos in cosmology," Phys. Rept. 370, 333 (2002); G. G. Raffelt, "Astrophysical and cosmological neutrinos," hep-ph/0208024. These papers give extensive references [69] A. D. Dolgov, S. H. Hansen, S. Pastor, S. T. Petcov, G. G. Raffelt and D. V. Semikoz, "Cosmological bounds on neutrino degeneracy improved by flavor oscillations," Nucl. Phys. B 632 (2002) 363 [70] E. Lisi, S. Sarkar and F. L. Villante, "The big bang nucleosynthesis limit on N " Phys. Rev. D 59 (1999) 123520 [71] C. Burgess et al, "Large mixing angle oscillations as a probe of the deep solar interior," hep-ph/0209094; H. Nunokawa et al, "The effect of random matter density perturbations...," Nucl. Phys. B 472, 495 (1996); A. B. Balantekin, J. M. Fetter and F. N. Loreti, "The MSW effect in a fluctuating matter density," Phys. Rev. D 54, 3941 (1996); P. Bamert, C. P. Burgess and D. Michaud, "Neutrino propagation through helioseismic waves," Nucl. Phys. B 513, 319 (1998) [72] M. T. Keil, G. G. Raffelt and H. T. Janka, "Monte Carlo study of supernova neutrino spectra formation," astro-ph/0208035.

61

[73] A. Y. Smirnov, D. N. Spergel, J. N. Bahcall, "Is Large Lepton Mixing Excluded?," Phys. Rev. D 49, 1389 (1994); B. Jegerlehner, F. Neubig, G. Raffelt, Phys. Rev. D 54, 1194 (1996); M. Kachelriess, R. Tomas, J. W. F. Valle, "Large lepton mixing and supernova 1987A," JHEP 0101, 030 (2001) [74] M. Kachelriess et al, "SN1987A and the status of oscillation solutions to the solar neutrino problem," Phys. Rev. D 65, 073016 (2002) [hep-ph/0108100]. [75] H. Minakata et al, "Probing supernova physics with neutrino oscillations," Phys. Lett. B 542, 239 (2002) [hep-ph/0112160]. [76] G.G. Raffelt, private communication [77] H. Nunokawa et al, "Resonant conversion of massless neutrinos in supernovae," Phys. Rev. D 54, 4356 (1996); H. Nunokawa et al, "Supernova bounds on supersymmetric R-parity violating interactions," Nucl. Phys. B 482, 481 (1996); D. Grasso et al, "Pulsar velocities without neutrino mass," Phys. Rev. Lett. 81, 2412 (1998). [78] G. L. Fogli, E. Lisi, A. Mirizzi and D. Montanino, "Revisiting nonstandard interaction effects on supernova neutrino flavor oscillations," Phys. Rev. D 66 (2002) 013009 and papers therein [79] M. Kachelriess, R. Tomas and J. W. F. Valle, "Supernova bounds on ma joron-emitting decays of light neutrinos," Phys. Rev. D 62 (2000) 023004 [hep-ph/0001039]. See also Y. Farzan, "Bounds on the coupling of the ma joron to light neutrinos from supernova cooling," hep-ph/0211375. [80] L. J. Hall and M. Suzuki, "Explicit R Parity Breaking In Supersymmetric Models," Nucl. Phys. B 231 (1984) 419; For a recent review see B. Allanach et al, "Searching for R-parity violation at Run-II of the Tevatron," hep-ph/9906224 [81] L. J. Hall, V. A. Kostelecky and S. Raby, "New Flavor Violations In Supergravity Models," Nucl. Phys. B 267 (1986) 415. R. Barbieri, L. J. Hall and A. Strumia, "Violations of lepton flavor and CP...," Nucl. Phys. B 445, 219 (1995); F. Gabbiani, E. Gabrielli, A. Masiero and L. Silvestrini, "A complete analysis of FCNC and CP...," Nucl. Phys. B 477 (1996) 321 [82] M. Guzzo et al, "Status of a hybrid three-neutrino interpretation of neutrino data," Nucl. Phys. B 629, 479 (2002) [hep-ph/0112310]. For early Refs. see [10, 41], and also M. M. Guzzo, A. Masiero and S. T. Petcov, "On the MSW effect with massless...," Phys. Lett. B 260 (1991) 15, and E. Roulet, "Mikheyev-Smirnov-Wolfenstein effect with flavor-changing...," Phys. Rev. D 44 (1991) 935. [83] M. C. Gonzalez-Garcia et al, "Atmospheric neutrino observations and flavor changing interactions," Phys. Rev. Lett. 82, 3202 (1999); N. Fornengo et al, JHEP 0007, 006 (2000) [84] K. Fujikawa and R. Shrock, "The Magnetic Moment Of A Massive Neutrino And Neutrino Spin Rotation," Phys. Rev. Lett. 45 (1980) 963. [85] A.I. Derbin et al., "Experiment On Anti-Neutrino Scattering by Electrons..." JETP Lett. 57 (1993) 768 [Pisma Zh. Eksp. Teor. Fiz. 57 (1993) 755]. A.V. Derbin, "Restriction On The Magnetic Dipole Moment Of Reactor Neutrinos," Phys. Atom. Nucl. 57 (1994) 222 [Yad. Fiz. 57 (1994) 236]. [86] H. B. Li [Texono Collaboration], "New limits on neutrino magnetic moments...," hep-ex/0212003. [87] C. Broggini, MUNU Collaboration, "Preliminary Results And Status Of The Munu Experiment," Nucl. Phys. (Proc. Suppl.) 100 (2001) 267; J. Vuilleumier, Talk at Neutrino 2002, Munich, http://neutrino2002.ph.tum.de/. [88] L. B. Auerbach et al. [LSND Collaboration], "Measurement of e electron elastic scattering," Phys. Rev. D 63 (2001) 112001

62

[89] R. Schwienhorst et al. [DONUT Collaboration], "A new upper limit for the tau-neutrino magnetic moment," Phys. Lett. B 513 (2001) 23 [90] G.G. Raffelt, "Limits On Neutrino Electromagnetic Properties: An Update," Phys. Rept. 320 (1999) 319. [91] B. S. Neganov et al, "Status of the experiment on the laboratory search for the electron antineutrino magnetic moment...," Phys. Atom. Nucl. 64 (2001) 1948 [Yad. Fiz. 64 (2001) 2033] [92] J. Schechter and J. W. F. Valle, "Ma jorana Neutrinos And Magnetic Fields," Phys. Rev. D 24, 1883 (1981) [Err.-ibid. D 25, 283 (1982)]. [93] A. Cisneros, "Effect Of Neutrino Magnetic Moment On Solar Neutrino Observations," Astrophys. Space Sci. 10 (1971) 87; L. B. Okun, M. B. Voloshin and M. I. Vysotsky, "Electromagnetic Properties Of Neutrino And Possible Semiannual Variation Of The Solar Neutrino Flux," Sov. J. Nucl. Phys. 44 (1986) 440 [94] G. Raffelt, "Stars as Laboratories for Fundamental Physics", University of Chicago Press (1996) [95] E. K. Akhmedov, "Resonant Amplification Of Neutrino Spin Rotation In Matter And The SolarNeutrino Problem," Phys. Lett. B 213 (1988) 64. C. S. Lim and W. J. Marciano, "Resonant SpinFlavor Precession Of Solar And Supernova Neutrinos," Phys. Rev. D 37 (1988) 1368. [96] O. G. Miranda et al, "The simplest resonant spin-flavour solution to the solar neutrino problem," Nucl. Phys. B 595, 360 (2001) [97] O. G. Miranda et al, "A non-resonant dark-side solution to the solar neutrino problem," Phys. Lett. B 521, 299 (2001) [hep-ph/0108145]. [98] J. Schechter and J. W. F. Valle, "Neutrino Decay And Spontaneous Violation Of Lepton Number," Phys. Rev. D 25 (1982) 774. [99] P. B. Pal and L. Wolfenstein, "Radiative Decays Of Massive Neutrinos," Phys. Rev. D 25 (1982) 766; S. Petcov, Sov. J. of Nucl. Phys. 24, 340 (1977); W. Marciano and A. Sanda, Phys. Lett. B67, 303 (1977). [100] J. M. Frere, R. B. Nevzorov and M. I. Vysotsky, "Stimulated neutrino conversion and bounds on neutrino magnetic moments," Phys. Lett. B 394 (1997) 127 [101] M. C. Gonzalez-Garcia and J. W. F. Valle, "Fast Decaying Neutrinos And Observable Flavor Violation In A New Class Of Ma joron Models," Phys. Lett. B 216 (1989) 360. [102] B. W. Lee and R. E. Shrock, "Natural Suppression Of Symmetry Violation In Gauge Theories: Muon - Lepton And Electron Lepton Number Nonconservation," Phys. Rev. D 16 (1977) 1444. [103] A. D. Dolgov et al, "Primordial nucleosynthesis, ma jorons...," Nucl. Phys. B 496 (1997) 24 [hep-ph/9610507]. [104] J. W. F. Valle, "Fast Neutrino Decay In Horizontal Ma joron Models," Phys. Lett. B 131 (1983) 87. [105] G. B. Gelmini, S. Nussinov and T. Yanagida, "Does Nature Like Nambu-Goldstone Bosons?," Nucl. Phys. B 219 (1983) 31. [106] A. Jodidio et al., "Search For Right-Handed Currents In Muon Decay," Phys. Rev. D 34 (1986) 1967 [Err-ibid. D 37 (1988) 237].

63

[107] V. D. Barger, W. Y. Keung and S. Pakvasa, "Ma joron Emission By Neutrinos," Phys. Rev. D 25 (1982) 907. [108] Z. G. Berezhiani et al, "Observable Ma joron emission in neutrinoless double beta decay," Phys. Lett. B 291 (1992) 99 [hep-ph/9207209]. [109] S. Pakvasa and K. Tennakone, "Neutrinos Of Non-Zero Rest Mass," Phys. Rev. Lett. 28 (1972) 1415; J. N. Bahcall, N. Cabibbo and A. Yahil, "Are Neutrinos Stable Particles?," Phys. Rev. Lett. 28 (1972) 316; J. N. Bahcall et al, "Tests Of Neutrino Stability," Phys. Lett. B 181 (1986) 369. [110] A. Bandyopadhyay, S. Choubey and S. Goswami, "Neutrino decay confronts the SNO data," hep-ph/0204173; A. S. Joshipura, E. Masso and S. Mohanty, "Constraints on decay plus oscillation solutions...," Phys. Rev. D 66 (2002) 113008 [111] P. Lipari and M. Lusignoli, Phys. Rev. D60, 013003 (1999); G. Fogli et al., Phys. Rev. D59, 117303(1999); S. Choubey and S. Goswami, Astropart. Phys. 14, 67(2000). [112] V. D. Barger, J. G. Learned, P. Lipari, M. Lusignoli, S. Pakvasa and T. J. Weiler, "Neutrino decay and atmospheric neutrinos," Phys. Lett. B 462 (1999) 109 [113] J. F. Beacom and N. F. Bell, "Do solar neutrinos decay?," Phys. Rev. D 65 (2002) 113009 [114] J. F. Beacom, N. F. Bell, D. Hooper, S. Pakvasa and T. J. Weiler, "Decay of high-energy astrophysical neutrinos," hep-ph/0211305. [115] N. Cabibbo, Phys. Lett. B 72, 333 (1978). S. Pakvasa, Proc. of the XXth Int. Conference on High Energy Physics, ed. by L. Durand and L.G.Pondrom, AIP Conf. Proc. No. 68 (New York, 1981), Vol. 2, p. 1164; V. Barger, K. Whisnant and R.N. Phillips, Phys. Rev. Lett. 45, 2084 (1980). [116] D. Colladay and V. A. Kostelecky, "CPT violation and the standard model," Phys. Rev. D 55, 6760 (1997) [117] S. R. Coleman and S. L. Glashow, "High-energy tests of Lorentz invariance," Phys. Rev. D 59, 116008 (1999) [118] V. D. Barger, S. Pakvasa, T. J. Weiler and K. Whisnant, "CPT odd resonances in neutrino oscillations," Phys. Rev. Lett. 85, 5055 (2000) [119] S. M. Bilenky, M. Freund, M. Lindner, T. Ohlsson and W. Winter, "Tests of CPT invariance at neutrino factories," Phys. Rev. D 65 (2002) 073024 [120] H. Murayama and T. Yanagida, "LSND, SN1987A, and CPT violation," Phys. Lett. B 520 (2001) 263; G. Barenboim, L. Borissov, J. Lykken and A. Y. Smirnov, "Neutrinos as the messengers of CPT violation," JHEP 0210 (2002) 001 [121] A. Suzuki, 8th International Workshop on Neutrino Telescopes, Venice, Feb. 23-26, 1999, Ed. M. Baldo-Ceolin, Vol. I. p. 325. [122] O. W. Greenberg, "CPT violation implies violation of Lorentz invariance," Phys. Rev. Lett. 89, 231602 (2002) [123] G. Baremboim, L. Borissov and J. Lykken, "CPT violating neutrinos in the light of KamLAND," hep-ph/0212116. [124] D. Colladay and V. A. Kostelecky, "Lorentz-violating extension of the standard model," Phys. Rev. D 58 (1998) 116002

64

[125] S. R. Coleman and S. L. Glashow, "Cosmic ray and neutrino tests of special relativity," Phys. Lett. B 405 (1997) 249 [hep-ph/9703240]. [126] See, e. g. C. W. Misner, K. S. Thorne, and J. A. Wheeler. "Gravitation". W. H. Freeman, San Francisco, 1973; or S. Weinberg, "Gravitation and Cosmology: Principles and Applications of the General Theory of Relativity", John Wiley & Sons, ISBN: 0471925675 [127] M. Gasperini, "Testing The Principle Of Equivalence With Neutrino Oscillations," Phys. Rev. D 38, 2635 (1988). [128] A. Halprin and C. N. Leung, "Can the sun shed light on neutrino gravitational interactions?," Phys. Rev. Lett. 67, 1833 (1991). [129] A. Halprin, C. N. Leung and J. Pantaleone, "A Possible Violation of the Equivalence Principle by Neutrinos," Phys. Rev. D 53, 5365 (1996) [130] J. Pantaleone, A. Halprin, C. N. Leung, "Neutrino Mixing Due Principle," Phys. Rev. D 47 (1993) 4199; J. N. Bahcall, P. I. Kras and the principle of equivalence," Phys. Rev. D 52 (1995) 1770; H. the principle of equivalence by solar neutrinos," Phys. Rev. D 51 to a Violation of the Equivalence tev, C. N. Leung, "Solar neutrinos Minakata, H. Nunokawa, "Testing (1995) 6625

[131] J.G. Learned, Current Aspects of Neutrino Physics, Ed. D. Caldwell, Springer-Verlag (2001), hep-ex/0107056; P. Lipari and M. Lusignoli, "On exotic solutions of the atmospheric neutrino problem," Phys. Rev. D 60, 013003 (1999); G. L. Fogli, E. Lisi, A. Marrone and G. Scioscia, "Testing violations of special and general relativity..." Phys. Rev. D 60, 053006 (1999) [132] A. Raychaudhuri and A. Sil, "Violation of the equivalence principle in the light of the SNO..." Phys. Rev. D 65, 073035 (2002); A. M. Gago, H. Nunokawa and R. Zukanovich Funchal, "The solar neutrino problem and gravitationally induced..." Phys. Rev. Lett. 84, 4035 (2000) [133] D. Naples et al. [CCFR/NuTeV Collaboration], "A high statistics search for e (e ) ( ) ? ? oscillations," Phys. Rev. D 59, 031101 (1999) and Phys. Rev. Lett. 78, 2912 (1997) [134] MINOS Collaboration, NUMI-2-375 Report (1998); NGS Report, CERN 98-02, INFN/AE-98-05 (1998). For the range accessible to neutrino factories, see A. Datta, Phys. Lett. B504, 247 (2001). [135] E. K. Akhmedov and J. Pulido, "Distinguishing magnetic moment from oscillation solutions..." Phys. Lett. B 529, 193 (2002); and Phys. Lett. B 553 (2003) 7 [136] Talk by J. Shirai, at http://neutrino2002.ph.tum.de/pages/transparencies2.html [137] S. Pastor et al, "Low-energy anti-neutrinos from the sun," Phys. Lett. B 423 (1998) 118 [138] B. Kayser, "Ma jorana Neutrinos and their Electromagnetic Properties," Phys. Rev. D 26 (1982) 1662; J. F. Nieves, "Electromagnetic Properties of Ma jorana Neutrinos," Phys. Rev. D 26 (1982) 3152. [139] W. Grimus et al, "Constraining Ma jorana neutrino electromagnetic properties from the LMAMSW solution of the solar neutrino problem," Nucl. Phys. B 648 (2003) 376 [hep-ph/0208132]; J. F. Beacom and P. Vogel, "Neutrino magnetic moments...," Phys. Rev. Lett. 83, 5222 (1999) [140] Z. Berezhiani, R. S. Raghavan and A. Rossi, "Probing non-standard couplings of neutrinos at the Borexino detector," Nucl. Phys. B 638, 62 (2002) [141] O. G. Miranda, V. Semikoz and J. W. F. Valle, "Neutrino electron scattering and electroweak gauge structure: Future tests," Phys. Rev. D 58, 013007 (1998) [hep-ph/9712215].

65

[142] I. Barabanov et al, "Testing for new physics with low-energy anti-neutrino sources: LAMA as a case study," Nucl. Phys. B 546 (1999) 19 [hep-ph/9808297]. [143] F. Abe et al. [CDF Collaboration], "Search for new gauge bosons decaying into dileptons in pp ? collisions at s = 1.8 - T eV " Phys. Rev. Lett. 79 (1997) 2192. [144] M. C. Gonzalez-Garcia and J. W. F. Valle, "Neutral Current And Lep Constraints On An Extra E(6) Neutral Gauge Boson: A Global Fit To Electroweak Parameters," Phys. Lett. B 259 (1991) 365. For a recent update see J. Erler and P. Langacker, in Ref. [47]. [145] M. Apollonio et al., "Oscillation physics with a neutrino factory," hep-ph/0210192; C. Albright et al., "Physics at a neutrino factory," hep-ex/0008064. These contain an extensive list of references [146] M. Freund, P. Huber and M. Lindner, "Systematic exploration of the neutrino factory parameter space including errors and correlations," Nucl. Phys. B 615 (2001) 331; A. Cervera, A. Donini, M. B. Gavela, J. J. Gomez Cadenas, P. Hernandez, O. Mena and S. Rigolin, Nucl. Phys. B 579 (2000) 17 [Err-ibid. B 593 (2001) 731]; A. De Rujula, M. B. Gavela, P. Hernandez, "Neutrino oscillation physics with a neutrino factory," Nucl. Phys. B 547 (1999) 2 [147] P. Huber and J. W. F. Valle, "Non-standard interactions: Atmospheric versus neutrino factory experiments," Phys. Lett. B 523, 151 (2001) [148] P. Huber, T. Schwetz and J. W. F. Valle, "How sensitive is a neutrino factory to the angle Theta(13)?," Phys. Rev. Lett. 88, 101804 (2002) [hep-ph 0111224] and "Confusing non-standard neutrino interactions with oscillations at a neutrino factory," Phys. Rev. D 66, 013006 (2002) [hep-ph 0202048]

66