Neutrinos with Lorentz-violating operators of arbitrary dimension (1112.6395v2)

Abstract: The behavior of fermions in the presence of Lorentz and CPT violation is studied. Allowing for operators of any mass dimension, we classify all Lorentz-violating terms in the quadratic Lagrange density for free fermions. The result is adapted to obtain the effective hamiltonian describing the propagation and mixing of three flavors of left-handed neutrinos in the presence of Lorentz violation involving operators of arbitrary mass dimension. A characterization of the neutrino coefficients for Lorentz violation is provided via a decomposition using spin-weighted spherical harmonics. The restriction of the general theory to various special cases is discussed, including among others the renormalizable limit, the massless scenario, flavor-blind and oscillation-free models, the diagonalizable case, and several isotropic limits. The formalism is combined with existing data on neutrino oscillations and kinematics to extract a variety of measures of coefficients for Lorentz and CPT violation. For oscillations, we use results from the short-baseline experiments LSND and MiniBooNE to obtain explicit sensitivities to effects from flavor-mixing Lorentz-violating operators up to mass dimension 10, and we present methods to analyze data from long-baseline experiments. For propagation, we use time-of-flight measurements from the supernova SN1987A and from a variety of experiments including MINOS and OPERA to constrain oscillation-free Lorentz-violating operators up to mass dimension 10, and we discuss constraints from threshold effects in meson decays and Cherenkov emission.

• The paper introduces a quadratic Lagrange density framework that extends neutrino oscillation analysis to include Lorentz-violating operators up to dimension 10.
• It systematically classifies Lorentz-violating terms using spin-weighted spherical harmonics, providing clear guidance for experimental investigations.
• The study proposes concrete experimental setups, such as time-of-flight and threshold measurements, to detect subtle Lorentz and CPT violation effects.

Insights into Neutrinos with Lorentz-Violating Operators of Arbitrary Dimension

The behavior of neutrinos in the presence of Lorentz and CPT violation is a crucial subject of paper, particularly given the evident manifestations of physics beyond the Standard Model (SM) in phenomena like neutrino oscillations. This paper by Kostelecký and Mewes explores the theoretical formulation and implications of Lorentz-violating operators across arbitrary dimensions in the context of neutrino physics. The primary objective is to extend the handling techniques of Lorentz violation in neutrinos to incorporate operators of various mass dimensions, which could potentially reveal subtle effects at increased energies.

Theoretical Framework

The comprehensive treatment begins with the construction of a general quadratic Lagrange density for free fermions, allowing for Lorentz-violating operators of any mass dimension. The paper classifies all Lorentz-violating terms necessary for this description and adapts the results to discuss the effective Hamiltonian for three flavors of left-handed neutrinos. A notable aspect of this paper is its consideration of operators beyond the renormalizable limit, extending the formalism to accommodate nonrenormalizable operators up to dimension 10.

The examination of neutrino coefficients for Lorentz violation is facilitated by a decomposition utilizing spin-weighted spherical harmonics. This is particularly significant for experimental analysis as it provides a systematic approach to classify the effects of Lorentz violation based on their rotational properties.

Special Models and Applications

The paper explores various special cases and models for those working within the field of neutrino physics:

1. Renormalizable Models: These models focus on operators of mass dimension four or less, providing insights consistent with the SME's renormalizable sector. This includes new effects appearing from interactions between neutrino masses and Lorentz-violating terms.
2. Massless Models: Here, the focus lies on scenarios where neutrino oscillations might occur without an intrinsic neutrino mass. This model's theoretical exploration is of particular interest because it challenges the traditional understanding that oscillation mandates mass acquisition.
3. Flavor-blind and Oscillation-free Models: These models are crucial when oscillations are negligible, such as investigating propagation speed differences from other particles like photons.
4. Isotropic Models: The isotropic scenarios, including diagonalizable models, imply Lorentz violation detectable as a function of direction with respect to a preferred frame, such as the cosmic microwave background, offering a simplified yet potent approach for studying rotational invariance.

Experimental Implications

Applying the theoretical insights gained from their formulations, the authors detail potential experimental setups that could be used to uncover effects of Lorentz-violating operators:

• Time-of-Flight Measurements: These experiments involve comparing the speed of neutrinos with other particles like photons to detect variations due to Lorentz-violating effects. The paper provides explicit methods to analyze data from long-baseline neutrino experiments.
• Threshold Effects: The work also explores how Lorentz-violating terms might influence the threshold for processes such as pion or kaon decay into neutrinos, which has significant experimental implications for high-energy neutrino detectors.
• Oscillation Experiments: The methods elucidated could vastly improve current neutrino oscillation experiments by more accurately identifying small deviations attributable to potential Lorentz and CPT violations.

Future Directions

The paper sets the stage for a comprehensive examination of neutrinos beyond SM physics frameworks, encouraging further exploration of these implications in ongoing and future neutrino experiments. By focusing on operators up to mass dimension 10, the authors extend the potential for experimental discovery, suggesting that many avenues of neutrino behavior unexplained by SM could indeed be pointing toward Lorentz and CPT violation effects.

The implications extend to practical techniques in setting up and analyzing neutrino-related experiments, encompassing not just the theoretical formulation but also grooves into real-world applications that could potentially refine our understanding of the universe at a fundamental level.