Hunting Beyond Standard Physics with DUNE’s Neutrino Beam

Author: Denis Avetisyan

A new analysis demonstrates how the DUNE-PRISM program can refine searches for exotic neutrino properties and deviations from known physics.

The search for sterile neutrinos benefits from a multi-channel approach-combining appearance and disappearance signatures-and is poised for significant advancement with DUNE-PRISM, which promises to expand sensitivity beyond current constraints established by experiments like MINOS+, KARMEN, NOMAD, and MicroBooNE, and potentially resolve anomalies suggested by LSND and MiniBooNE results at <span class="katex-eq" data-katex-display="false">99\%</span> confidence level. — The search for sterile neutrinos benefits from a multi-channel approach-combining appearance and disappearance signatures-and is poised for significant advancement with DUNE-PRISM, which promises to expand sensitivity beyond current constraints established by experiments like MINOS+, KARMEN, NOMAD, and MicroBooNE, and potentially resolve anomalies suggested by LSND and MiniBooNE results at $99\%$ confidence level.

The DUNE-PRISM setup offers enhanced sensitivity to non-unitarity and sterile neutrinos by mitigating spectral shape uncertainties at the DUNE near detector.

Precision searches for new physics in neutrino oscillations are fundamentally limited by systematic uncertainties in neutrino flux predictions and cross sections. This work, ‘Sharpening New Physics Searches in Neutrino Oscillations with DUNE-PRISM’, investigates the potential of the Precision Reaction Independent Spectrum Measurement (PRISM) technique to mitigate these limitations within the Deep Underground Neutrino Experiment (DUNE). We demonstrate that PRISM can substantially reduce the impact of spectral uncertainties, restoring sensitivity to scenarios involving non-unitarity and sterile neutrinos to levels comparable to those achievable with precisely known fluxes. Will this data-driven approach unlock the full potential of DUNE to probe beyond the Standard Model and reveal the subtle signatures of new neutrino physics?

The Whispers of Mass: Unveiling the Neutrino’s Secret

The observation of neutrino oscillations fundamentally altered the landscape of particle physics, providing the first conclusive evidence that neutrinos possess mass. For decades, the Standard Model posited neutrinos as massless particles, yet experiments consistently revealed that these elusive particles transform between three distinct “flavors” – electron, muon, and tau – as they travel. This transformation, or oscillation, is only possible if neutrinos have mass, a property not initially included in the Standard Model. The implications of this discovery are profound, necessitating extensions to the Standard Model to accommodate massive neutrinos and opening new avenues of research into the nature of these fundamental particles and their role in the universe. Determining the precise masses and mixing parameters of neutrinos remains a central challenge, promising insights into phenomena such as the matter-antimatter asymmetry in the cosmos and the universe’s large-scale structure.

The detection of neutrino oscillations, while confirming neutrinos possess mass, presents a formidable experimental challenge. Accurately quantifying these oscillations isn’t simply a matter of observing the phenomenon; it demands meticulous attention to exceedingly subtle effects. Neutrinos interact weakly with matter, meaning signals are inherently faint and easily obscured by background noise. Furthermore, extracting precise oscillation parameters requires a deep understanding – and rigorous control – of systematic uncertainties. These arise from imperfections in detector calibration, uncertainties in the initial neutrino beam characteristics, and even the Earth’s density along the neutrino’s path. Minimizing these uncertainties isn’t a matter of improving statistics; it necessitates innovative detector technologies, sophisticated data analysis techniques, and a comprehensive theoretical framework to model all potential sources of error, pushing the boundaries of experimental precision in particle physics.

A significant challenge facing contemporary neutrino oscillation experiments lies in the precise characterization of the initial neutrino beam itself. Determining the flux, energy spectrum, and flavor composition of neutrinos at the source is crucial for interpreting observed oscillation patterns, yet this remains a complex undertaking. Imperfections in modeling the production and focusing of these elusive particles introduce systematic uncertainties that directly impact the extraction of fundamental parameters like mixing angles and mass differences. These uncertainties aren’t merely statistical fluctuations; they represent a fundamental limitation on the precision with which scientists can probe neutrino properties and, consequently, refine the Standard Model. Efforts are continually underway to improve beam calibration techniques, refine simulation models, and develop novel methods for in situ beam characterization, all aimed at reducing these systematic errors and unlocking a more complete understanding of neutrino behavior.

Neutrino energy spectra at the DUNE Near Detector, calculated using a <span class="katex-eq" data-katex-display="false">\tau\tau</span>-optimized beam for various off-axis angles, reveal dominant <span class="katex-eq" data-katex-display="false">\nu_\mu</span> and <span class="katex-eq" data-katex-display="false">\overline{\nu}_\mu</span> fluxes alongside smaller <span class="katex-eq" data-katex-display="false">\nu_e</span>, <span class="katex-eq" data-katex-display="false">\overline{\nu}_e</span>, <span class="katex-eq" data-katex-display="false">\nu_\tau</span>, and <span class="katex-eq" data-katex-display="false">\overline{\nu}_\tau</span> contributions primarily from decay processes. — Neutrino energy spectra at the DUNE Near Detector, calculated using a $\tau\tau$ -optimized beam for various off-axis angles, reveal dominant $\nu_\mu$ and $\overline{\nu}_\mu$ fluxes alongside smaller $\nu_e$ , $\overline{\nu}_e$ , $\nu_\tau$ , and $\overline{\nu}_\tau$ contributions primarily from decay processes.

DUNE: A Glimmer of Order in a Chaotic Universe

The Deep Underground Neutrino Experiment (DUNE) aims to significantly improve the current understanding of neutrino oscillations – the process by which neutrinos change “flavor” (electron, muon, or tau) during propagation. DUNE will achieve this through the observation of muon neutrino disappearance and electron neutrino appearance in a long-baseline neutrino beam originating from the Long-Baseline Neutrino Facility (LBNF) at Fermilab. The experiment is designed to measure the oscillation parameters – specifically the mixing angles and mass-squared differences – with a precision unattainable by previous and current experiments. This enhanced precision will allow for tests of the Standard Model of particle physics and potentially reveal discrepancies that could indicate new physics beyond the Standard Model, including CP violation in the lepton sector, which could help explain the matter-antimatter asymmetry in the universe.

The DUNE Near Detector (ND-LAr) is positioned along the neutrino beamline 280 meters from the source to precisely characterize the initial neutrino flux before oscillation can occur. This detector employs Liquid Argon Time Projection Chamber (LArTPC) technology, which allows for three-dimensional reconstruction of neutrino interactions with millimeter-scale resolution. By meticulously measuring the energy, flavor composition, and interaction characteristics of the original neutrino beam, the ND-LAr provides crucial normalization data for the far detector, enabling accurate interpretation of oscillation results and reducing systematic uncertainties in the measurement of neutrino mixing parameters. The LArTPC operates by ionizing argon atoms as neutrinos interact, creating tracks of charge that are then drifted and imaged, providing a detailed record of the interaction vertex and particle trajectories.

Detailed simulations are integral to the DUNE experiment due to the complexity of neutrino interactions and the large scale of the detectors. G4LBNF, a simulation toolkit based on Geant4, models the entire experimental setup, including the neutrino beamline, the Near and Far Detector components, and the surrounding infrastructure. These simulations are used to predict the expected detector response to known neutrino interactions, allowing researchers to refine detector design parameters, optimize event reconstruction algorithms, and accurately estimate systematic uncertainties. Specifically, G4LBNF provides crucial information on particle propagation, energy deposition, and the resulting signals in the Liquid Argon Time Projection Chamber (LArTPC), which is vital for interpreting experimental data and precisely measuring neutrino oscillation parameters. The fidelity of these simulations is continuously validated against test beam data and smaller-scale prototype experiments.

Neutrino and antineutrino fluxes at the DUNE Near Detector, as a function of energy and for various off-axis angles, show distinct patterns for <span class="katex-eq" data-katex-display="false">\nu_{\mu}</span>, <span class="katex-eq" data-katex-display="false">\overline{\nu}_{\mu}</span>, <span class="katex-eq" data-katex-display="false">\nu_{e}</span>, and <span class="katex-eq" data-katex-display="false">\overline{\nu}_{e}</span> as detailed in the accompanying data files. — Neutrino and antineutrino fluxes at the DUNE Near Detector, as a function of energy and for various off-axis angles, show distinct patterns for $\nu_{\mu}$ , $\overline{\nu}_{\mu}$ , $\nu_{e}$ , and $\overline{\nu}_{e}$ as detailed in the accompanying data files.

DUNE-PRISM: A Network of Foresight

The DUNE-PRISM strategy utilizes a network of detectors positioned at varying off-axis angles relative to the proton beam. This multi-detector approach allows for the independent measurement of the neutrino flux and cross-section at multiple locations, providing redundancy and enabling robust constraints on systematic uncertainties. By comparing neutrino interactions observed at different off-axis angles, experimenters can differentiate between genuine neutrino oscillation effects and potential biases arising from imperfect knowledge of the initial neutrino beam characteristics or detector response. This effectively reduces the correlation of systematic errors, leading to a more precise determination of oscillation parameters and enhanced sensitivity to new physics.

Off-axis detector configurations modify the incident neutrino energy spectrum by shifting the peak energy and reducing the overall flux compared to a on-axis setup. This alteration is crucial for optimizing sensitivity to specific neutrino oscillation parameters, particularly those related to the mass-splitting and mixing angles. By tailoring the energy spectrum, researchers can enhance the measurement of oscillation probabilities at specific energies, improving the precision with which these parameters can be determined. The effect is particularly pronounced for parameters governing oscillations in the few-GeV energy range, relevant to the DUNE experiment’s primary physics goals, by increasing the number of events occurring at energies where the oscillation probability is most sensitive to changes in those parameters.

The DUNE-PRISM strategy mitigates the impact of spectral shape uncertainties on neutrino oscillation measurements by leveraging multiple off-axis detector positions. These positions effectively sample different portions of the initial neutrino beam spectrum, providing redundancy and allowing for precise characterization of any spectral distortions. This approach yields a reduction in spectral shape uncertainties of up to a factor of two, directly improving the precision with which oscillation parameters can be determined. Consequently, the enhanced precision translates to increased sensitivity in searches for new physics beyond the Standard Model, such as sterile neutrinos or deviations from three-flavor oscillations.

The addition of DUNE-PRISM significantly enhances sensitivity to off-diagonal non-unitarity parameters <span class="katex-eq" data-katex-display="false">|α_{μe}|</span>, potentially excluding a larger region of parameter space at 90% confidence level as indicated by the shaded blue region, despite a 5% shape uncertainty. — The addition of DUNE-PRISM significantly enhances sensitivity to off-diagonal non-unitarity parameters $|α_{μe}|$ , potentially excluding a larger region of parameter space at 90% confidence level as indicated by the shaded blue region, despite a 5% shape uncertainty.

Beyond the Standard Model: Echoes of the Unknown

The Deep Underground Neutrino Experiment (DUNE) presents a distinctive opportunity to investigate the existence of sterile neutrinos, particles beyond those described in the Standard Model of particle physics. Current neutrino oscillation experiments have revealed anomalies that hint at physics not fully accounted for, and sterile neutrinos offer a potential explanation for these discrepancies. Unlike the three known neutrino flavors – electron, muon, and tau – sterile neutrinos would not interact via the weak force, making their detection extraordinarily challenging. DUNE’s innovative design, featuring a far detector with unprecedented scale and sensitivity, is specifically optimized to search for the subtle signatures of sterile neutrino mixing, potentially resolving these existing anomalies and revolutionizing the understanding of fundamental neutrino properties.

The Deep Underground Neutrino Experiment (DUNE) offers a crucial test of the $3 \times 3$ Pontecorvo-Maki-Nakagawa-Sakata (PMNS) matrix, a cornerstone of the Standard Model describing neutrino mixing. This matrix dictates the probabilities of neutrinos changing “flavor” – electron, muon, or tau – as they travel. A fundamental tenet of the Standard Model is that the PMNS matrix must be unitary, meaning the total probability of a neutrino being in any flavor must equal one. Deviations from unitarity would signal physics beyond the Standard Model, potentially indicating the existence of new particles or interactions. DUNE’s precise measurements of neutrino appearance and disappearance rates, coupled with its ability to reconstruct neutrino energies, provide the statistical power necessary to rigorously test this unitarity condition and search for subtle violations that could reshape the understanding of fundamental particles and forces.

The Deep Underground Neutrino Experiment – Proton Removable Ice Module (DUNE-PRISM) represents a significant leap forward in the search for physics beyond the Standard Model. Through innovative detector technology, DUNE-PRISM is projected to enhance sensitivity to deviations from the unitarity of the Pontecorvo-Maki-Nakagawa-Sakata (PMNS) matrix by as much as a factor of two across specific parameter spaces. Critically, the experiment offers an unprecedented one order of magnitude improvement in the detection of sterile neutrino mixing – hypothetical neutrinos that do not interact via the weak force – with particular strength in identifying mass splittings $\Delta m^2_{4} < 20 \text{ eV}^2$ . This heightened sensitivity promises to either confirm or refute the existence of these elusive particles and could fundamentally reshape understanding of neutrino properties and the broader landscape of particle physics.

DUNE, and particularly with the addition of DUNE-PRISM and a <span class="katex-eq" data-katex-display="false"> au- au</span>-optimized beam (blue band), is projected to significantly improve sensitivity to sterile-neutrino appearance beyond current experimental constraints (pink and gray areas) at 90% confidence level. — DUNE, and particularly with the addition of DUNE-PRISM and a $au- au$ -optimized beam (blue band), is projected to significantly improve sensitivity to sterile-neutrino appearance beyond current experimental constraints (pink and gray areas) at 90% confidence level.

Unveiling the Ghost Particle: The Tau Neutrino’s Turn

The Deep Underground Neutrino Experiment (DUNE) represents a pivotal advancement in the pursuit of understanding tau neutrinos, the most elusive of the three neutrino flavors. Currently, observations of tau neutrinos are exceptionally rare, hindering comprehensive studies of their properties and interactions. DUNE’s far greater detector mass and intense neutrino beam, coupled with innovative detection techniques, are projected to increase the observed rate of tau neutrino interactions by orders of magnitude. This surge in data will allow physicists to precisely measure tau neutrino oscillation parameters, probe potential differences in its behavior compared to other neutrino flavors, and search for evidence of new physics beyond the Standard Model – ultimately unlocking the secrets of this least understood fundamental particle and potentially revolutionizing neutrino physics.

The Deep Underground Neutrino Experiment (DUNE) is poised to dramatically improve tau neutrino detection through a specifically engineered beam configuration. This “tau-optimized beam” focuses on maximizing the production of these elusive particles, which are notoriously difficult to observe due to their extremely short lifetimes and decay characteristics. By increasing the sheer number of tau neutrinos generated, the experiment substantially boosts the event rate – the frequency with which these particles interact and are detected. This, in turn, significantly improves the statistical power of DUNE, allowing physicists to discern true signals from background noise with greater confidence and ultimately unlocking a more detailed understanding of neutrino properties and interactions. The ability to reliably detect and study tau neutrinos is crucial, as they represent a largely unexplored frontier in particle physics and may hold keys to phenomena beyond the Standard Model.

The Deep Underground Neutrino Experiment (DUNE) stands to gain significantly from the implementation of a tau-optimized beam, not merely in detecting these elusive particles, but in pushing the boundaries of physics beyond the Standard Model. By tailoring the beam’s energy profile to maximize tau neutrino production, researchers anticipate a substantial boost in the sensitivity of the DUNE-PRISM technique – a method designed to search for sterile neutrinos and other exotic phenomena. This optimized approach doesn’t just increase the number of observable tau neutrino events; it fundamentally enhances the experiment’s ability to discern subtle deviations from expected behavior, potentially revealing the existence of new particles or interactions previously hidden from view. The increased statistical power afforded by this beam configuration promises a more precise investigation of neutrino properties and a greater likelihood of uncovering physics that could redefine current understandings of the universe.

DUNE-PRISM significantly enhances sensitivity to off-diagonal non-unitarity parameters <span class="katex-eq" data-katex-display="false">|\alpha\_{\tau\mu}|</span>, increasing the excluded parameter space at 90% C.L. (shaded grey area) and further improving with a <span class="katex-eq" data-katex-display="false">\tau\tau</span>-optimized beam (shaded blue region) despite a 5% shape uncertainty. — DUNE-PRISM significantly enhances sensitivity to off-diagonal non-unitarity parameters $|\alpha\_{\tau\mu}|$ , increasing the excluded parameter space at 90% C.L. (shaded grey area) and further improving with a $\tau\tau$ -optimized beam (shaded blue region) despite a 5% shape uncertainty.

The pursuit of precision in neutrino oscillation studies, as detailed in this exploration of DUNE-PRISM, reveals a familiar pattern. It isn’t about constructing a flawless instrument, but about anticipating the inevitable distortions of reality. As Bertrand Russell observed, “The whole problem with the world is that fools and fanatics are so confident of their own opinions.” This confidence often manifests as a belief in perfect modeling, ignoring the spectral shape uncertainties inherent in complex systems. The DUNE-PRISM program doesn’t seek to eliminate these uncertainties, but to understand and account for their decay, acknowledging that every attempt at measurement is, at its core, a prediction of future imperfection.

The Horizon Recedes

The pursuit of precision in neutrino oscillation studies, as exemplified by the DUNE-PRISM program, is not a convergence on truth, but the charting of increasingly subtle failure modes. Mitigation of spectral shape uncertainties is a temporary reprieve, a delaying of the inevitable confrontation with the limits of measurement. A system that perfectly models the background is, functionally, dead; it has exhausted its capacity for surprise, and therefore for discovery. The focus on non-unitarity and sterile neutrinos, while logically sound given current anomalies, implicitly accepts the premise that solutions will resemble the questions – a comforting, but often misleading, assumption.

The true value of programs like DUNE-PRISM lies not in confirming or denying specific hypotheses, but in revealing the architecture of its own limitations. Each refined uncertainty estimate is a prophecy of a more insidious, previously unconsidered systematic error. The near detector, intended as a precise calibration tool, becomes a mirror reflecting the inherent incompleteness of any model.

Future progress will not hinge on achieving ever-greater precision, but on developing the humility to embrace irreducible ambiguity. The field requires a shift in focus: not toward building better instruments, but toward cultivating a more sophisticated understanding of what those instruments cannot tell us. Perfection, after all, leaves no room for people – or for the unexpected signals that ultimately drive progress.

Original article: https://arxiv.org/pdf/2604.20951.pdf

Contact the author: https://www.linkedin.com/in/avetisyan/