Current experiments do not exclude the possibility that one or more neutrinos are very slightly superluminal or that they have a very small tachyonic mass. Important bounds on the size of a hypothetical tachyonic neutrino mass term are set by lepton pair Čerenkov radiation (LPCR), that is, by the decay channel ν→e+e-ν, which proceeds via a virtual Z0 boson. Here, we use a Lorentz-invariant dispersion relation which leads to very tight constraints on the tachyonic mass of neutrinos; we also calculate decay and energy loss rates. A possible cutoff seen in the IceCube neutrino spectrum for Eν>2 PeV, due to the potential onset of LPCR, is discussed.
National Science FoundationPHY-14039731. Introduction
The early arrival of a neutrino burst from the 1987A supernova [1] still motivates speculations about a possible superluminal nature of neutrinos, even if it is generally assumed that the delay in the arrival of electromagnetic radiation (light) is caused by the time the shock wave from the core collapse needs in order to reach the surface of the exploding star. If neutrinos are ever so slightly superluminal, then they may emit Čerenkov radiation in the form of light lepton pairs. In this paper, we attempt to answer three questions: (i) How would the energy threshold for the decay channel ν→e+e-ν (lepton pair Čerenkov radiation, LPCR) have to be calculated if we assume a strictly Lorentz-covariant, space-like dispersion relation for the relevant neutrino flavor eigenstate? (ii) How would the decay rate and the energy loss rate have to be calculated under this assumption? Can the tachyonic Dirac equation [2–5] and its bispinor solutions [6, 7] be used in that context? (iii) What implications could be derived for astrophysics under the assumption that a possible cutoff seen by IceCube for neutrinos with energies Eν>2 PeV is confirmed by future experiments?
Theoretical arguments can be useful in restricting the possible degree of superluminality of neutrinos and maximum attainable neutrino velocities [8–10]. In [8, 9], a Lorentz-noncovariant dispersion relation Eν=p→vν was used, where vν>c is a constant parameter. This assumption leads to an energy-dependent effective “mass” square Eν2-p→2≈Eν2(vν2-1)vν-2≡meff2. The effective mass meff=Eνvν2-1vν-1 then grows linearly with the neutrino energy. (Natural units with ħ=c=ϵ0=1 are used in this paper, yet we shall include explicit factors of c when indicated by the context.) Indeed, at the time, a best fit to the available experimental neutrino mass data including the initial OPERA claim [11] suggested the conceivable existence of an “energy-dependent mass” of the neutrino, as evidenced in Figure 1 of [12]. The choice of the relation Eν=|p→|vν made in [8] was consistent with the need to model the initial OPERA claim [11] and is perfectly compatible with the concept of perturbative Lorentz breaking terms in the neutrino sector [9]. A Dirac-type equation leading to the Lorentz-noncovariant dispersion relation used by Cohen and Glashow [8] can be obtained [9] from the current operator given in Eq. (2) of [13] upon a particular choice of cμν parameters in the generalized fermionic current operator (in the notation adopted in [13]). Then, assuming a constant neutrino speed vν>c, one can effectively describe the apparent absence of energy dependence of the deviation of the neutrino speed from the speed of light vν≈const.≳c (in the range 5GeV<Eν<50 GeV), according to the (falsified) initial claim made by OPERA [11], while remaining compatible with the framework of perturbative Lorentz breaking [13].
However, while there are advantages to assuming a Lorentz-noninvariant dispersion relation for superluminal neutrinos (such as the preservation of the timelike positive quantity Eν2-p→2>0), there are also a number of disadvantages. For example, if the dispersion relation Eν=|p→|vν holds in one particular Lorentz frame, then, under a Lorentz boost, in general, one has Eν′≠|p→′|vν in the moving frame [8, 9]. In order to illustrate the consequences of Lorentz noncovariance, let us consider a boost along positive z-axis into a frame which moves with velocity u=c2/vν<c. A particle moving along positive z-axis of the lab frame with four-momentum pμ=(|p→|vν,|p→|e^z) is mapped onto p′μ=(|p→|vν2-1,0→) and thus is “at rest” in the moving frame. However, the general dispersion relation in the moving frame,(1)Eν′=-pz′2vν-px′2+py′2+pz′2vν2pz′pz′≠0,is much more complicated. (Throughout this paper, we denote the spatial components of the four-vector pμ=(Eν,p→) by p→ and keep |p→| explicitly in order to avoid confusion between p2=pμpμ and p2≠p→2.)
An alternative, commonly accepted dispersion relation for so-called tachyons (these are space-like, faster-than-light particles described by a Lorentz-invariant wave equation) reads as Eν2=p→2-mν2; that is, it is the “normal” dispersion relation with the negative sign of the mass square term (see [2–7, 14–23]). Here, we calculate the threshold energy and the decay rate under the assumption of a Lorentz-invariant dispersion relation for the neutrino. We find that the alternate dispersion relation imposes tight restrictions on superluminality and has important phenomenological implications for neutrino masses.
2. Dispersion Relations and Thresholds
For tachyonic particles, starting from the pioneering work of Sudarshan et al. [14–16], continuing with the works of Feinberg [17, 18], and including the tachyonic neutrino hypothesis [2–6, 19–23], the following dispersion relation has been assumed for the tachyonic (space-like) solutions: (2a)Eν=γνmν,p→ν=γνmνvν,(2b)p→ν=Eνvν,pμpμ=Eν2-p→ν2=-mν2,where we use the suggestive subscript ν for “neutrino.” These relations imply that p→=Eνvν instead of Eν=p→vν. Here, the tachyonic Lorentz factor appears, which is γν=1/vν2-1. Tachyonic and tardyonic dispersion relations are unified upon assuming an imaginary value for m in the tachyonic case (starting from the tardyonic case, one has E=m/1-v2→im/1-v2=m/v2-1, where the latter equation holds for tachyons). With the standard definitions of p→ and Eν, one has p→ν=γνmvν=Eνvν for both tardyons and tachyons.
In order to obtain the threshold energy for the LPCR decay ν→e+e-ν, we use the following conventions (see Figure 1), inspired by Chap. 10 of [24], and define E1=p→12-mν2 and E3=p→32-mν2 as the oncoming and outgoing neutrino energies, with q=(E1,p→1)-(E3,p→3) being the four-momentum of Z0. Pair production threshold is reached for q2=4me2 and cosθ=p1→·p3→/(p→1p→3)=1. For collinear geometry, with all momenta pointing along z-axis, we have(3)q2=p1z2-mν2-p3z2-mν22-p1z-p3z2=4me2.Furthermore, threshold obviously requires E3=0. (This is possible for tachyonic particles, when p→3=p3z=mν. In this limit, the tachyonic particle becomes infinitely fast and loses all of its energy, which implies that it is impossible to detect it [25]. The counterintuitive loss of energy for tachyons under acceleration is a consequence of standard tachyonic kinematics [2, 6, 7, 14–18, 26–28].) When the relations E3=0 and p→3=p3z=mν are substituted into (3), this yields(4)p1z2-mν2-p1z-mν2=4me2.Identifying p1z=p→th with the threshold momentum, one easily finds(5)p→th=2me2mν+mν.The threshold energy is then easily found as(6)Eth=p→th2-mν2=2memνme2+mν2≈2me2mν.Because we are using a tachyonic dispersion relation, the threshold energy can be expressed as a function of only the mass parameters. Larger tachyonic masses mν lead to lower threshold energies. In view of the tachyonic dispersion relation mν=Ethvth2-1, where vth is the neutrino velocity at threshold, we may convert the threshold energy into a function of the electron mass and the neutrino threshold velocity. For given Eν, the limit mν≪me is equivalent to the limit vth2-1=δth→0 because mν=Eνδth. In this limit, we have(7)Eth≈2me2mν=2me2Ethvth2-1⟹Eth≈2mevth2-11/4.Substituting the exact dispersion relation into the threshold condition Eth=2(me/mν)me2+mν2, and solving for Eth, one obtains(8)Eth=2me1+vthvth2-11/2=2meδth1/4δth≪12me+me4δthδth≫1.The exact expression (8) confirms (7) in the limit δν≪1, which corresponds to the phenomenologically important limit of high-energy neutrinos. Smaller values of δth (approaching zero) correspond to smaller tachyonic neutrino masses and therefore to larger threshold energies. For given neutrino speed vth, neutrinos with energy Eth (or larger), under the hypothetical assumption of the tachyonic dispersion relation, have a tachyonic neutrino mass term large enough to make the decay via LPCR kinematically possible. Expressed differently, the tachyonic mass term mν=Ethvth2-1 in this case is large enough to lead to LPCR decay at energy Eth, according to (6).
Conventions for tachyonic neutrino decay.
3. Decay Rate and Timelike Noncovariant Dispersion Relation
Given the complexities of calculating the decay rate due to LPCR using a tachyonic dispersion relation, it is extremely useful to first discuss the case of a Lorentz-noncovariant form Eν=p→vν, using lab frame variables. For collinear incoming and outgoing neutrinos, threshold for pair production is reached at q2=(E1-E3)2-(p1z-p3z)2=(p1z-p3z)2(vν2-1)=4me2, from which one derives (setting p→3=0→) the following threshold values (in agreement with [8]):(9)p→1th=2mevν2-1,E1th=2mevνvν2-1.Here, GF is Fermi’s coupling constant and u and v are the standard fundamental positive-energy and negative-energy bispinor solutions of the Dirac equation [29]. The invariant matrix element is(10)M=GF2u¯p3γλ1-γ5up1×u¯p4cVγλ-cAγλγ5vp2.Here, cV≈0, and cA≈-1/2 [see Eq. (5.57) on p. 153 of [30]]. Following [9], we now make the additional assumption that the functional form of the projector sum over the spin orientations remains the same as for the ordinary Dirac equation even if the underlying dispersion relation is Lorentz-noncovariant (for a general discussion on such models, see [31, 32]). In this case, the sum over final state and the averaging over the initial spins leads to (1/2)∑spinsM2=64GF2(p1·p2)(p3·p4). This enters the lab frame expression for the decay rate [33]:(11)Γ=12E1∫d3p32π32E3∫d3p22π32E2∫d3p42π32E4×2π4δ4p1-p3-p2-p412∑spinsM2=GF212π42E1∫d3p32E3p1·p3q2+2p1·qp3·q,where q=p1-p3. The azimuthal symmetry suggests the use of cylindrical coordinates. The domain of integration contains, for given p1=(p1zvν,0,0,p1z), all permissible p→3=p3ρe^ρ+p3ze^z, where p3μ=(p→3vν,p→3). With Eν=p→vν, the momentum transfer is(12)q2=-p1z-p3z2-p3ρ2+p1z-p3ρ2+p3z22vν2,where we require q2>4me2≈0. Solving (12) for p3ρ, one obtains the boundary of the region of permissible p→3 vectors. An example is given in Figure 2(a) in the form of a “sharpened ellipsoid” with “sharp” top near p3ρ→0, p3z→p1z, and a “rounded” bottom with p3ρ→0, and p3z→-[(vν-1)/(vν+1)]p1z. After somewhat tedious integration over the allowed p→3 vectors, one obtains(13)Γ=GF22688π3p1z5δν3vν≈114GF2Eν5δν3192π3dEνdx≈-GF296π42Eν∫q2>0d3p32E3Eν-E3×p1·p3q2+2p1·qp3·q=-GF286016π3p1z6δν3vν≈-25448GF2Eν6δν3192π3,for the energy loss per unit length, confirming the results given in Eq. (2) and Eq. (3) of [8] and in [9]. This confirmation of the results given in [8] (under the assumptions made in the cited paper, namely, the dispersion relation Eν=p→vν), but using a different method, namely, phase-space integration directly in the laboratory frame, encourages us to apply the same method to the calculation of the tachyonic neutrino decay rate, where the use of the laboratory frame is indispensable. The confirmation also underlines the consistency of the theoretical formalism under a change of the assumptions made in the calculation.
(a) Region of allowed outgoing momenta p→3 for the decay of an incoming superluminal neutrino with Eν=p→vν. The neutrino is incoming along positive z-axis (p1z=15). The boundary of allowed p→3 vectors constitutes a distorted ellipsoid with a “sharpened tip,” obtained as a solution of setting q2=0 in (12). (b) Region of allowed p→3 vectors for an incoming tachyonic neutrino with p1z=62 and -mν2=-(0.2)2, producing an electron-positron pair of mass me=1 (dispersion relation Eν=p→ν2-mν2). Final wave vectors p→3<mν correspond to evanescent waves and are thus to be excluded [6].
4. Decay Rate and Space-Like Covariant Dispersion Relation
For an incoming tachyon, the particle state (space-like neutrino) may transform into an antiparticle state upon Lorentz transformation, and its trajectory may reverse the time ordering (see Figure 3). Thus, the interpretation of a tachyonic neutrino state as a particle or antiparticle may depend on the frame of reference, and we should calculate the process directly in the lab frame. The necessity to transform certain tachyonic particle field operators into antiparticle operators under Lorentz boosts has been stressed in [6, 17, 18]. Incoming and outgoing states are required to be above-threshold positive-energy states in the lab frame (causality and tachyonic trajectories are discussed in [2, 14–18] and Appendix A.2 of [34]).
The world line 1↦2↦3 describes the tachyonic neutrino decay into a zero-energy, infinitely fast neutrino. Complete reversal of the time ordering of the decay process takes place in the primed frame; the observer interprets the process as the decay of an incoming antineutrino along the trajectory 3↦2↦1.
We consider the matrix element(14)M=GF2u¯Tp3γλ1-γ5uTp1×u¯p4cVγλ-cAγλγ5vp2.Here, uT(p1) and uT(p3) are Dirac spinor solutions of the tachyonic Dirac equation [6, 7]. The bar denotes the Dirac adjoint. In the helicity basis (see Chap. 23 of [35] and [6, 7]), these are given by(15)u±Tp=p→±ma±p→±p→∓ma±p→,where a±(p→) are the fundamental helicity spinors (see p. 87 of [29]). Following [6, 7, 19], we use the tachyonic sum rule of the fundamental tachyonic bispinor solutions [see Eq. (34a) of [6]]:(16)∑σ-σuσTp⊗u¯σTpγ5=p-γ5m,where p=(E,p→) is the four-momentum and σ is a helicity quantum number. We refer to [6, 7] for a thorough discussion; roughly speaking, factor (-σ) in (16) restores the correct sign in the calculation of the time-ordered product of tachyonic field operators (the propagator) for the contribution of all virtual degrees of freedom of the tachyonic field [see Eqs. (46)–(57) and Eq. (73)–(75) of [7]]. γ5 matrix in (16) is a part of the natural Dirac “adjoint” for the tachyonic spinor. Namely, the adjoint equation to the tachyonic Dirac equation, iγμ∂μ-γ5mψ(x)=0, reads as ψ¯(x)γ5(iγμ∂←μ-γ5m)ψ(x)=0. As explained in Eqs. (73)–(75) of [17], right-handed particle states and left-handed antiparticle states (those with the “wrong” helicity) are excluded from the physical spectrum of the tachyonic field by a Gupta-Bleuler condition; these cannot contribute to the oncoming and outgoing neutrino states in Figure 1 [while they do contribute to the virtual states, that is, the propagator; see Eqs. (46)–(57) of [7]]. Both the incoming and the outgoing neutrinos in Figure 1 are real rather than virtual neutrinos. Hence, in order to calculate the LPCR decay rate, we use the modified sum over tachyonic spinors:(17)∑σ~uσTp⊗u¯σTp=1+γ5τp^p-γ5mνγ5,where τ=(1,0,0,0) is a timelike unit vector, p^=p→/|p→| is the unit vector in p→ direction, and upon promotion to a four-vector, we have p^μ=(0,p^), so that 1+γ5τp^=1-Σ→·p→/|p→| becomes a left-handed helicity projector.
We thus calculate with an incoming, positive-energy, left-helicity tachyonic neutrino. One obtains the modified sum over spins ∑~spins in the matrix element:(18)∑spins~M2=GF22Tr121+γ5τp^3p3-γ5mνγ5γλ1-γ5121+γ5τp^1p1-γ5mνγ5γν1-γ5Kλρ.Here, Kλρ=Tr[(p4+me)cVγλ-cAγλγ5(p2+me)cVγρ-cAγργ5] is the familiar trace from the outgoing fermion pair. The decay rate is given by (11) under the replacement (1/2)∑spins|M|2→∑~spins|M|2. The integrals over the momenta of the outgoing fermion pair (d3p2 and d3p4) are done using (p22=p42=me2). Consider(19)Jλρq=∫d3p22E2∫d3p42E4δ4q-p2-p4p2λp4ρ=π241-4me2q2gλρq2-4me2+2qλqρ1+2me2q2.It remains to analyze the domain of allowed p→3 vectors [see the “cupola structure” in Figure 2(b)], which is defined by the requirement q2>4me2, for p1μ=(p1z2-mν2,0,0,p1z). The dispersion relation Eν=p→ν2-mν2 implies that(20)q2=2E12+mν2E32+mν2cosθ-E1E3-mν2.Here, θ is the polar angle in spherical coordinates:(21)p3μ=E3,p→3sinθcosφ,p→3sinθsinφ,p→3cosθ.Pair production threshold is reached, for given E1 and E3, by solving (20) for u=cosθ, setting q2=4me2. After somewhat tedious integration over the allowed p→3 vectors (no masses can be neglected), one obtains (22a)Γ=GF2mν6128π3me2Eν-Eth2EthEν>≈EthGF2mν4288π3EνEν≫Eth,for the decay rate, and(22b)dEνdx=GF2mν564π3Eν-Eth2EthEν>≈EthGF2mν4144π3E12Eν≫Eth,for the energy loss rate. In the high-energy limit, one may (somewhat trivially) rewrite the expressions as follows (mν=E1δν):(23)Γ=GF2Eν5δν2288π3,dEνdx=GF2Eν6δν2144π3,Eν≫Eth.These results confirm that it is possible to use the tachyonic bispinor formalism [2–7] for the calculation of decay rates of tachyonic particles.
5. Constraints on the Mass of a Tachyonic Neutrino
Our threshold relation (8) is based on a Lorentz-covariant dispersion relation. Only neutrinos with Eν<Eth=2me/δth1/4 survive the possibility of generalized leptonic Čerenkov radiation over a sufficiently long path length. The hypothetical observation of an absence of neutrinos above some energy Eth could thus be interpreted as a constraint on the neutrino mass. Let us assume a neutrino mass of mν=X eV, where X is generally assumed to be of order unity or less. Then, threshold is reached for mν=X eV, δth=3.67×10-24X4, and Eth=(522/X) GeV.
The IceCube experiment [36, 37] has observed 37 neutrinos having energies Eν>10 TeV during 3 years of data taking. Three of these events had energies Eν>1 PeV, and one (often referred to as “Big Bird”) had Eν=(2.004±0.236) PeV. According to the IceCube collaboration [37], the spectrum of the 37 neutrinos is well fitted by a slope ~Eν-2, which includes astrophysical as well as background atmospheric neutrinos, the latter being exclusively below 0.4 PeV. However, their best fit to the spectrum predicts 3.1 additional events for Eν>2 PeV, and yet none were seen. Preliminary data for the fourth year includes 17 additional events, with none seen for Eν>1 PeV [38]. These facts suggest to the IceCube authors [36, 37] the possibility that there may be a cutoff for the spectrum for neutrinos above E≈2 PeV. The hypothesis is given further support by models which show that the Glashow resonance [39] (resonant ν¯ee-→W-→anything) should add between zero and three times the number of events that appear in the interval 1PeV<Eν<2PeV as part of a broad peak centered around 6.3 PeV [40]. While evidence for the cutoff is disputed and alternative explanations have been proposed [41], the significance of such a cutoff has been analyzed in the light of superluminal neutrinos [42, 43].
Let us add a few clarifying remarks here. First, we note that the plots in the paper [37] refer to the neutrino flux as a function of neutrino energy; the events were apparently sufficiently well reconstructed so that no excess neutrino energy in addition to the energy deposited inside the detector is expected. Our Figure 4 is based on Figure 4 of [37]. Meanwhile, members of the IceCube collaboration have presented preliminary evidence for a throughgoing muon of energy ≥(2.6±0.3) PeV which could be interpreted as a decay product of a neutrino of even higher energy [44, 45]. If the throughgoing muon could indeed be assigned to an ultra-high-energy neutrino of nonatmospheric origin, then it would push the conceivable cutoff seen by IceCube to even higher energies, further constraining the tachyonic mass term of the relevant neutrino flavor. So far, the authors of [37] (see the right column on page 4 of [37]) observe that “this [the lack of high-energy events] may indicate, along with the slight excess in lower energy bins, either a softer spectrum or a cutoff at high energies.”
Three years of data from the IceCube experiment showing flux dNν/dEν multiplied by Eν2 plotted against the neutrino energy Eν. The solid and dashed curves show what would be expected for Eν-2 power law for the flux, with Eth=2.5 PeV threshold, and two arbitrarily assumed values for the source distance, L (dashed curve) and L/2 (solid curve). The drop to zero above Eth only occurs for those neutrino flavors having a tachyonic mass consistent with a 2.5 PeV threshold.
Assuming Eth≈2 PeV we would find using (8) that δth=(2me/Eth)4≈1.7×10-38, and we would, furthermore, find that mν=δthEth≈0.00026 eV (i.e., -mν2≈-6.8×10-8 eV2) for one or more of the three neutrino flavors (conceivably, the one with the smallest absolute value of mν2). A shifted cutoff [44, 45] of Eth≈3 PeV would be consistent with a tachyonic neutrino mass of mν=0.00017 eV. One might object that it is not possible to have one (or more) tachyonic flavor masses (m2<0) and satisfy both neutrino oscillation data and the recent findings from cosmology for the sum of the flavor masses; that is, Σm≈0.32 eV [46, 47]. However, such consistency can be achieved using 3 active-sterile ±m2 (tardyon-tachyon) neutrino pairs [48]. The curves in Figure 4 were generated using an assumed pure Eν-2 power law for flux N beyond the assumed threshold, Eth. We then use our dEν/dx formula (22b) for Eν>Eth to find the modified NEν2 spectrum. Good agreement is found with the IceCube data at a threshold Eth=2.5 PeV, although much more statistics will be needed to determine if the cutoff is real.
6. Conclusions
Three main conclusions of the current investigation can be drawn. (i) As described in Section 2, the assumption of a Lorentz-covariant, tachyonic dispersion relation leads to tight bounds on conceivable tachyonic neutrino mass terms, for whatever neutrino flavor is causing the possible 2 PeV cutoff. The tachyonic decay rate due to LPCR is most conveniently calculated in the laboratory frame because of the space-like kinematics involved in the process, which leads to a nonunique time ordering of the trajectories, as discussed in Section 4. (ii) We may apply the formalism of the tachyonic bispinor solutions of the tachyonic Dirac equation [2–5] recently developed in [6, 7, 19] to the calculation of the tachyonic neutrino decay, as outlined in Section 4. (iii) A comparison of recent IceCube data with the results for the calculated tachyonic decay rates reveals that a tachyonic neutrino could possibly explain a possible sharp cutoff in IceCube data but only if the neutrino flavor involved has a very specific tachyonic mass. In a more general context, the calculation of tachyonic thresholds and decay rates based on Lorentz-covariant dispersion relations could be of phenomenological significance for string theories, some of which predict the existence of tachyons [49, 50]. The same is true for the precise calculation of the tail of the beta decay spectrum, which is influenced by a conceivably tachyonic neutrino mass term [51].
Competing Interests
The authors declare that there are no competing interests regarding the publication of this paper.
Acknowledgments
This research has been supported by the National Science Foundation (Grant no. PHY-1403973).
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