Dec 18, 2020
KATRIN: a still unsterilized scale!
KATRIN: a still unsterilized scale!

Figure 1: picture of the inside of the spectrometer of the KATRIN experiment. ©KATRIN collaboration.

The main objective of the KATRIN experiment is the measurement of the mass of the three neutrinos of the Standard Model of Particle Physics. But the analysis of the beta decay spectrum of tritium also allows to search for the trace of a hypothetical fourth neutrino, called sterile neutrino. The collaboration has just published its first analysis in Physical Review Letters (see article) based on four weeks of data acquired in 2019. There is no trace of this fourth neutrino, but this is only the beginning as sensitivity will rapidly improve. The KATRIN spectrometer shows a strong potential to study this possible new facet of the neutrino.

 

The KATRIN experience

 

The international experiment called KATRIN, composed of 20 institutes from 7 countries and located at the Karlsruhe Institute of Technology (KIT) in Germany, is designed to measure the mass of neutrinos with unprecedented accuracy. It is thus sometimes considered as the most accurate "balance" in the world (see figure 1).

The operating principle of the experiment is shown in figure 2. For 60 billion electrons per second emitted by the source, the spectrometer sorts out those whose energy is close to the maximum energy of the beta spectrum, and only 2 million electrons are kept for analysis.

After overcoming many technological challenges between 2001 and 2018, the 70 m long experiment started taking data in 2019. The in-depth analysis of a first scientific campaign corresponding to 4 weeks of data collection forced the neutrino mass to less than 1.1 eV (see corresponding article). This is now the best direct measurement of the neutrino mass (see FM Irfu KATRIN 2019).

 

Figure 2: schematic diagram of the KATRIN installation. A gaseous source contains molecules of di-tritium (3H-3H), whose nuclei decay by beta radioactivity into helium 3 (3He) to emit electrons (e-) and electron antineutrinos. The electrons are transported to the spectrometer, which selects those whose energy exceeds a predefined value (called delay potential) before they reach the detector. By varying the value of the delay potential, the energy spectrum of the electrons can be reconstructed thanks to a pixelized detector located at the end of the spectrometer, with an energy resolution of 3 eV. The fine analysis of this spectrum makes it possible to constrain the mass of the neutrino and the search for hypothetical sterile neutrinos. © KATRIN Collaboration adapted by APS/Alan Stonebraker.

 

 

Sterile neutrinos

  The current paradigm refers to three neutrinos, electronic, muonic, and tauic. However, this well-established picture may suffer from abnormal results from some experiments examining short-range neutrino oscillations (see FM Irfu RAA of 2011 and FM Irfu Stereo of 2019). If these are not experimental artifacts, then these results can be interpreted as the existence of one or more additional neutrino family(ies), mainly sterile, mixing with the three known active flavors while remaining insensitive to weak interaction.

 

The search for sterile neutrinos in KATRIN

 

It is also possible to constrain the mass (m4) and mixture (|Ue4|2) of a hypothetical sterile neutrino with the data of the KATRIN experiment. Indeed, a new mass state of the fourth neutrino would manifest itself by a distortion of the energy spectrum of the beta decay electrons. The signature would be an elbow-shaped break in the expected smooth spectrum of tritium electrons, as shown in a simulation presented in figure 3 b.

Figure 3: a) Electron spectrum of tritium including 4 weeks of data. The energy of the measured electrons is expressed here relative to the beta decay energy of tritium (or "endpoint" energy, equal to 18,574 eV here). b) Ratio of the KATRIN data points to the predicted spectrum in a model with 3 active neutrinos. The simulation of an arbitrary footprint of a fourth sterile neutrino on the spectrum is indicated by the red line. c) Distribution of the measurement time by energy interval. © KATRIN collaboration.

 

 

First result for KATRIN

 

In the article that has just been accepted for publication in Physical Review Letters, the KATRIN collaboration presents a first search for the signature of a sterile neutrino. The dataset analyzed is identical to the one used for the mass measurement of the neutrino in 2019. This research includes 1.5 million electrons from the beta decay of tritium, and 0.4 million electrons used to characterize the background noise. In this analysis, the signal-to-noise ratio can reach up to 70, well beyond what is usually achieved in reactor oscillation experiments (of the order of 1). This first KATRIN study is sensitive to m4 mass values (≈√Δm241 because m1 ? 1 eV) ranging from about 2 to 40 eV, and no significant sterile neutrino signals are observed (see figure 3 b). Thus, new exclusion limits are obtained (see figure 4). This result improves the limits set by the previous direct kinematics experiments carried out in Mainz (Germany) and Troitsk (Russia) in the late 1990s.

 

Figure 4: Exclusion curves obtained from KATRIN data. For each of them, the region located on the right of the curve is excluded, and the region located on the left remains allowed. The inside of the green contour delineates the neutrino oscillations, in a model with 3 active flavors and one sterile flavor, allowed by the reactor and Gallium anomalies. The results of KATRIN improve the exclusion of high m4 values compared to the measurements of the experiments carried out with the reactors (Stereo, DANSS, PROSPECT, etc.). The exclusion curves of experiments similar to KATRIN, Mainz and Troitsk are also drawn. An estimate of the final sensitivity of KATRIN is represented by the dotted line. Grey bands delimit the exclusions of the double beta decay experiments. © KATRIN collaboration.

 

 

Comparison to neutrino oscillation experiments

 

This research conducted by KATRIN is complementary to reactor experiments and improves their constraints in the regime of large masses (>10 eV). In addition, a significant fraction of the space of possible parameters indicated by the anomalies (reactor and Gallium, see FM Irfu RAA) is excluded, essentially for large masses of fourth neutrino. This result shows the potential of KATRIN to probe the sterile neutrino hypothesis with the same data collected that were used to constrain the mass of active neutrinos.

 

The IRFU's role

 

At the IRFU particle physics department, Thierry Lasserre coordinated the analysis for the whole KATRIN collaboration, establishing an innovative data processing strategy. In collaboration with the Max Planck Institut für Physik (Munich), he has also developed a new comprehensive analysis chain using the covariance matrix approach to study and propagate systematic errors and their correlations.

 

A search to follow

 

These initial results used only a small fraction (a few percent) of the statistics that will be available at the end of the experiment in 2024. In parallel, many efforts are underway to reduce systematic uncertainties and background noise, the latter being a limiting factor in probing the most relevant areas of the anomalies (fourth low-mass neutrino). An estimate of the final sensitivity of KATRIN (1000 days) is represented by the dotted line in Figure 4. A large part of the region of interest of the reactor and gallium anomalies will thus be tested to shed light on the existence of sterile neutrino mixtures.

 

Contact: Thierry Lasserre

 
#4882 - Last update : 02/05 2021

 

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