pith. sign in

arxiv: 2605.30709 · v1 · pith:53NDDZCUnew · submitted 2026-05-29 · ⚛️ physics.ins-det · hep-ex

Characterizing the energy resolution of the MicroBooNE LArTPC at the MeV scale using monoenergetic features of ²⁰⁸Tl decays

MicroBooNE collaboration: P. Abratenko , D. Andrade Aldana , J. Asaadi , A. Ashkenazi , S. Balasubramanian , B. Baller , A. Barnard , G. Barr
show 183 more authors
D. Barrow J. Barrow V. Basque J. Bateman B. Behera O. Benevides Rodrigues S. Berkman A. Bhat M. Bhattacharya V. Bhelande A. Binau M. Bishai A. Blake B. Bogart T. Bolton M.B. Brunetti L. Camilleri D. Caratelli F. Cavanna G. Cerati A. Chappell Y. Chen J.M. Conrad M. Convery L. Cooper-Troendle J.I. Crespo-Anadon R. Cross M. Del Tutto S.R. Dennis P. Detje R. Diurba Z. Djurcic K. Duffy S. Dytman B. Eberly P. Englezos A. Ereditato J.J. Evans C. Fang B.T. Fleming W. Foreman D. Franco A.P. Furmanski F. Gao D. Garcia-Gamez S. Gardiner G. Ge S. Gollapinni E. Gramellini P. Green H. Greenlee L. Gu W. Gu R. Guenette L. Hagaman M. D. Handley O. Hen A. Hergenhan M. Harrison S. Hawkins C. Hilgenberg G.A. Horton-Smith A. Hussain B. Irwin M.S. Ismail C. James X. Ji J.H. Jo A. Johnson R.A. Johnson D. Kalra G. Karagiorgi W. Ketchum A. Kelly M. Kirby T. Kobilarcik K. Kumar N. Lane J.-Y. Li Y. Li K. Lin B.R. Littlejohn L. Liu S. Liu W.C. Louis X. Luo T. Mahmud N. Majeed C. Mariani J. Marshall D.A. Martinez Caicedo F. Martinez Lopez M. G. Manuel Alves S. Martynenko A. Mastbaum I. Mawby N. McConkey B. McConnell L. Mellet J. Mendez J. Micallef T. Mohayai A. Mogan M. Mooney A.F. Moor C.D. Moore L. Mora Lepin M. A. Hernandez Morquecho M.M. Moudgalya S. Mulleria Babu D. Naples A. Navrer-Agasson N. Nayak M. Nebot-Guinot C. Nguyen L. Nguyen J. Nowak N. Oza O. Palamara N. Pallat V. Paolone A. Papadopoulou V. Papavassiliou H. Parkinson S.F. Pate N. Patel Z. Pavlovic E. Piasetzky K. Pletcher I. Pophale X. Qian J.L. Raaf V. Radeka A. Rafique M. Reggiani-Guzzo J. Rodriguez Rondon M. Rosenberg M. Ross-Lonergan I. Safa C. Sauer D.W. Schmitz A. Schukraft W. Seligman M.H. Shaevitz R. Sharankova J. Shi L. Silva E.L. Snider S. Soldner-Rembold J. Spitz M. Stancari J. St. John T. Strauss A.M. Szelc N. Taniuchi K. Terao C.Thorpe D. Torbunov D. Totani M. Toups A. Trettin Y.-T. Tsai J. Tyler M.A. Uchida T. Usher B. Viren J. Wang L. Wang M. Weber H. Wei A.J. White S. Wolbers T. Wongjirad K. Wresilo W. Wu E. Yandel T. Yang L.E. Yates H.W. Yu G.P. Zeller J. Zennamo C. Zhang Y. Zhang
This is my paper

Pith reviewed 2026-06-28 20:18 UTC · model grok-4.3

classification ⚛️ physics.ins-det hep-ex
keywords energy resolutionLArTPCMeV scale208Tl decayspair productionMicroBooNEliquid argonneutrino detector
0
0 comments X

The pith

MicroBooNE measures LArTPC energy resolution of 7.52% at 1.5 MeV using thallium gamma rays.

A machine-rendered reading of the paper's core claim, the machinery that carries it, and where it could break.

This paper measures the energy resolution of the MicroBooNE liquid argon time projection chamber at energies around 1.5 MeV. It uses monoenergetic gamma rays from thallium-208 decays that produce electron-positron pairs in the detector. The measured resolution is 7.52 percent with statistical and systematic uncertainties. This value matches the simulation prediction within 1.6 standard deviations. Such a measurement provides a way to calibrate detectors for low-energy neutrino physics.

Core claim

The energy resolution of the MicroBooNE LArTPC at approximately 1.5 MeV is measured to be (7.52 ± 0.78 (stat) ± 0.92 (syst))% using monoenergetic signals from 2.614 MeV gamma-rays undergoing pair production. This is consistent with the simulation prediction of (9.70 ± 0.65 (stat))% at the 1.6 σ level, marking the first such measurement at the MeV scale.

What carries the argument

Monoenergetic signals generated by 2.614 MeV γ-rays from 208Tl decays undergoing pair production in the detector, used to characterize the reconstructed energy resolution.

If this is right

  • This provides a pathway for monoenergetic energy calibrations in future LArTPC experiments.
  • It supports a detailed understanding of low-energy reconstruction capabilities for MeV-scale neutrino physics.
  • The consistency with simulation validates the use of Monte Carlo models for energy resolution predictions at this scale.

Where Pith is reading between the lines

These are editorial extensions of the paper, not claims the author makes directly.

  • The method could be adapted to verify resolution in other noble-liquid detectors operating at similar energies.
  • Improved low-energy calibration may reduce systematic uncertainties in neutrino interaction measurements below a few MeV.
  • Repeated application in next-generation detectors could establish a standard calibration benchmark independent of simulation.

Load-bearing premise

The selected events are cleanly dominated by pair-production deposits from the 2.614 MeV 208Tl gamma line with backgrounds and other detector effects sufficiently controlled to allow a direct resolution extraction.

What would settle it

An independent measurement of energy resolution at 1.5 MeV in the same or a similar LArTPC that falls outside the combined 1.6 σ agreement window with the reported 7.52% value.

read the original abstract

A detailed understanding of the capabilities and fidelity of low-energy reconstruction is crucial for taking advantage of MeV-scale neutrino physics opportunities in liquid argon time projection chambers (LArTPCs). This study presents a measurement of the resolution of reconstructed energy in the MicroBooNE LArTPC at $\approx 1.5$ MeV. The characterization is performed using monoenergetic signals generated by $2.614$ MeV $\gamma$-rays from $^{208}$Tl decays undergoing pair production in the detector. The resolution is found to be ($7.52 \pm 0.78 \text{(stat)} \pm 0.92 \text{(syst)}$)%. This value is consistent with the MicroBooNE simulation prediction of ($9.70 \pm 0.65 \text{(stat)}$)% at the $1.6 \sigma$ level. This study represents the first ever measurement of LArTPC energy resolution at the MeV scale and provides a pathway for monoenergetic energy calibrations in future experiments using LArTPC detectors.

Editorial analysis

A structured set of objections, weighed in public.

Desk editor's note, referee report, simulated authors' rebuttal, and a circularity audit. Tearing a paper down is the easy half of reading it; the pith above is the substance, this is the friction.

Referee Report

0 major / 0 minor

Summary. The manuscript reports the first measurement of energy resolution in the MicroBooNE LArTPC at the MeV scale (~1.5 MeV), extracted from monoenergetic pair-production deposits of 2.614 MeV γ-rays from 208Tl decays. The resolution is measured as (7.52 ± 0.78 (stat) ± 0.92 (syst))% and found consistent with the simulation prediction of (9.70 ± 0.65 (stat))% at the 1.6σ level.

Significance. If the result holds, this provides the first direct experimental benchmark of LArTPC energy resolution at MeV energies, directly supporting low-energy reconstruction for neutrino physics applications. The use of an in-situ monoenergetic feature from natural radioactivity offers a practical calibration pathway for future LArTPC experiments, and the reported consistency between data and simulation strengthens confidence in detector modeling at these scales.

Simulated Author's Rebuttal

0 responses · 0 unresolved

We thank the referee for their positive review of our manuscript, their recognition of its significance as the first direct measurement of LArTPC energy resolution at the MeV scale, and their recommendation to accept.

Circularity Check

0 steps flagged

No significant circularity; direct experimental measurement

full rationale

The paper reports an experimental extraction of LArTPC energy resolution from selected data events associated with the 2.614 MeV 208Tl gamma line. No derivation chain, parameter fit, or self-citation is shown to reduce the quoted resolution value to an input by construction. The result is obtained from data with statistical and systematic uncertainties evaluated separately from simulation comparison. This is a standard measurement paper whose central claim does not rely on any of the enumerated circularity patterns.

Axiom & Free-Parameter Ledger

0 free parameters · 1 axioms · 0 invented entities

The central claim is an experimental measurement resting on standard assumptions about pair-production kinematics, known 208Tl decay properties, and the detector's response model; no free parameters or invented entities are introduced in the abstract.

axioms (1)
  • domain assumption Pair production of 2.614 MeV gamma rays produces a monoenergetic energy deposit at 1.022 MeV above threshold that can be used to characterize resolution.
    Invoked implicitly as the basis for selecting the calibration feature (abstract).

pith-pipeline@v0.9.1-grok · 6725 in / 1290 out tokens · 20594 ms · 2026-06-28T20:18:17.014065+00:00 · methodology

discussion (0)

Sign in with ORCID, Apple, or X to comment. Anyone can read and Pith papers without signing in.

Reference graph

Works this paper leans on

48 extracted references · 1 canonical work pages

  1. [1]

    Capozziet al.,DUNE as the Next-Generation Solar Neutrino Experiment,Phys

    F. Capozziet al.,DUNE as the Next-Generation Solar Neutrino Experiment,Phys. Rev. Lett.123 (2019) 131803

  2. [2]

    Abiet al.(DUNE Collaboration),Supernova neutrino burst detection with the Deep Underground Neutrino Experiment,Eur

    B. Abiet al.(DUNE Collaboration),Supernova neutrino burst detection with the Deep Underground Neutrino Experiment,Eur. Phys. J. C81(2021) 423

  3. [3]

    Kubotaet al.(Q-Pix Collaboration),Enhanced low-energy supernova burst detection in large liquid argon time projection chambers enabled by Q-Pix,Phys

    S. Kubotaet al.(Q-Pix Collaboration),Enhanced low-energy supernova burst detection in large liquid argon time projection chambers enabled by Q-Pix,Phys. Rev. D106(2022) 032011

  4. [4]

    Acciarriet al.(ArgoNeuT Collaboration),Improved Limits on Millicharged Particles Using the ArgoNeuT Experiment at Fermilab,Phys

    R. Acciarriet al.(ArgoNeuT Collaboration),Improved Limits on Millicharged Particles Using the ArgoNeuT Experiment at Fermilab,Phys. Rev. Lett.124(2020) 131801

  5. [5]

    Harnik, Z

    R. Harnik, Z. Liu, and O. Palamara,Millicharged Particles in Liquid Argon Neutrino Experiments, JHEP07(2019) 170

  6. [6]

    Abratenkoet al.(MicroBooNE Collaboration),Search for light sterile neutrinos with two neutrino beams at MicroBooNE,Nature648(2025) 64

    P. Abratenkoet al.(MicroBooNE Collaboration),Search for light sterile neutrinos with two neutrino beams at MicroBooNE,Nature648(2025) 64

  7. [7]

    Abratenkoet al.(MicroBooNE Collaboration),Search for long-lived heavy neutral leptons and Higgs portal scalars decaying in the MicroBooNE detector,Phys

    P. Abratenkoet al.(MicroBooNE Collaboration),Search for long-lived heavy neutral leptons and Higgs portal scalars decaying in the MicroBooNE detector,Phys. Rev. D106(2022) 092006

  8. [8]

    Abratenkoet al.(MicroBooNE Collaboration),Search for Heavy Neutral Leptons in Electron-Positron and Neutral-Pion Final States with the MicroBooNE Detector,Phys

    P. Abratenkoet al.(MicroBooNE Collaboration),Search for Heavy Neutral Leptons in Electron-Positron and Neutral-Pion Final States with the MicroBooNE Detector,Phys. Rev. Lett.132 (2024) 041801

  9. [9]

    Abratenkoet al.(MicroBooNE Collaboration),Demonstration of neutron identification in neutrino interactionsintheMicroBooNEliquidargontimeprojectionchamber,Eur.Phys.J.C84(2024)1052

    P. Abratenkoet al.(MicroBooNE Collaboration),Demonstration of neutron identification in neutrino interactionsintheMicroBooNEliquidargontimeprojectionchamber,Eur.Phys.J.C84(2024)1052

  10. [10]

    D. O. Rivera,Neutron Cross Section Measurement In The Protodune-SP Experiment, PhD Thesis, University of Pennsylvania, 2021, FERMILAB-THESIS-2021-31

  11. [11]

    Acciarriet al.(ArgoNeuT Collaboration),Demonstration of MeV-scale physics in liquid argon time projection chambers using ArgoNeuT,Phys

    R. Acciarriet al.(ArgoNeuT Collaboration),Demonstration of MeV-scale physics in liquid argon time projection chambers using ArgoNeuT,Phys. Rev. D99(2019) 012002

  12. [12]

    Friedland and S

    A. Friedland and S. W. Li,Understanding the energy resolution of liquid argon neutrino detectors, Phys. Rev. D99(2019) 036009

  13. [13]

    Abiet al.(DUNE Collaboration),Volume IV

    B. Abiet al.(DUNE Collaboration),Volume IV. The DUNE far detector single-phase technology, JINST15(2020) T08010

  14. [14]

    Andringaet al.,Low-energy physics in neutrino LArTPCs,J

    S. Andringaet al.,Low-energy physics in neutrino LArTPCs,J. Phys. G50(2023) 033001. – 15 –

  15. [15]

    Castiglioniet al.,Benefits of MeV-scale reconstruction capabilities in large liquid argon time projection chambers,Phys

    W. Castiglioniet al.,Benefits of MeV-scale reconstruction capabilities in large liquid argon time projection chambers,Phys. Rev. D102(2020) 092010

  16. [16]

    P. A. N. Machado, O. Palamara, and D. W. Schmitz,The Short-Baseline Neutrino Program at Fermilab,Annu. Rev. Nucl. Part. Sci.69(2019) 363

  17. [17]

    Benettiet al.(WARP Collaboration),First results from a Dark Matter search with liquid Argon at 87 K in the Gran Sasso Underground Laboratory,Astropart

    P. Benettiet al.(WARP Collaboration),First results from a Dark Matter search with liquid Argon at 87 K in the Gran Sasso Underground Laboratory,Astropart. Phys.28(2008) 495

  18. [18]

    Agneset al.(DarkSide Collaboration),Low-Mass Dark Matter Search with the DarkSide-50 Experiment,Phys

    P. Agneset al.(DarkSide Collaboration),Low-Mass Dark Matter Search with the DarkSide-50 Experiment,Phys. Rev. Lett.121(2018) 081307

  19. [19]

    C. E. Aalsethet al.(DarkSide-20k Collaboration),DarkSide-20k: A 20 tonne two-phase LAr TPC for direct dark matter detection at LNGS,Eur. Phys. J. Plus133(2018) 131

  20. [20]

    Foremanet al.(LArIAT Collaboration),Calorimetry for low-energy electrons using charge and light in liquid argon,Phys

    W. Foremanet al.(LArIAT Collaboration),Calorimetry for low-energy electrons using charge and light in liquid argon,Phys. Rev. D101(2020) 012010

  21. [21]

    Abratenkoet al.(MicroBooNE Collaboration),Measurement of ambient radon progeny decay rates and energy spectra in liquid argon using the MicroBooNE detector,Phys

    P. Abratenkoet al.(MicroBooNE Collaboration),Measurement of ambient radon progeny decay rates and energy spectra in liquid argon using the MicroBooNE detector,Phys. Rev. D109(2024) 052007

  22. [22]

    Amorusoet al.(ICARUS Collaboration),Measurement of the𝜇decay spectrum with the ICARUS liquid Argon TPC,Eur

    S. Amorusoet al.(ICARUS Collaboration),Measurement of the𝜇decay spectrum with the ICARUS liquid Argon TPC,Eur. Phys. J. C33(2004) 233

  23. [23]

    Acciarriet al.(MicroBooNE Collaboration),Michel electron reconstruction using cosmic-ray data from the MicroBooNE LArTPC,JINST12(2017) P09014

    R. Acciarriet al.(MicroBooNE Collaboration),Michel electron reconstruction using cosmic-ray data from the MicroBooNE LArTPC,JINST12(2017) P09014

  24. [24]

    M. A. Hernandez-Morquechoet al.(LArIAT Collaboration),Measurements of Pion and Muon Nuclear Capture at Rest on Argon in the LArIAT Experiment,Phys. Rev. Lett.134(2025) 131801

  25. [25]

    Bhat,MeV Scale Physics in MicroBooNE, PhD Thesis, Syracuse University, 2021, FERMILAB-THESIS-2021-14

    A. Bhat,MeV Scale Physics in MicroBooNE, PhD Thesis, Syracuse University, 2021, FERMILAB-THESIS-2021-14

  26. [26]

    MicroBooNE Collaboration,Study of Reconstructed39Ar Beta Decays at the MicroBooNE Detector, MICROBOONE-NOTE-1050-PUB

  27. [27]

    MicroBooNE Collaboration,MeV-scale Physics in MicroBooNE, MICROBOONE-NOTE-1076-PUB

  28. [28]

    Abratenkoet al.(MicroBooNE Collaboration),Observation of radon mitigation in MicroBooNE by a liquid argon filtration system,JINST17(2022) P11022

    P. Abratenkoet al.(MicroBooNE Collaboration),Observation of radon mitigation in MicroBooNE by a liquid argon filtration system,JINST17(2022) P11022

  29. [29]

    Abratenkoet al.(MicroBooNE Collaboration),Demonstration of new MeV-scale capabilities in large neutrino LArTPCs using ambient radiogenic and cosmogenic activity in MicroBooNE,Phys

    P. Abratenkoet al.(MicroBooNE Collaboration),Demonstration of new MeV-scale capabilities in large neutrino LArTPCs using ambient radiogenic and cosmogenic activity in MicroBooNE,Phys. Rev. D111(2025) 032005

  30. [30]

    Kolanoski and N

    H. Kolanoski and N. Wermes,Particle Detectors: Fundamentals and Applications, Oxford University Press (2020)

  31. [31]

    Short-Baseline Near Detector (SBND): Design and Initial Performance

    R. Acciarriet al.,A Proposal for a Three Detector Short-Baseline Neutrino Oscillation Program in the Fermilab Booster Neutrino Beam, arXiv:1503.01520 (2015)

  32. [32]

    Abed Abudet al.(DUNE Collaboration),Design, construction and operation of the ProtoDUNE-SP Liquid Argon TPC,JINST17(2022) P01005

    A. Abed Abudet al.(DUNE Collaboration),Design, construction and operation of the ProtoDUNE-SP Liquid Argon TPC,JINST17(2022) P01005

  33. [33]

    Abiet al.(DUNE Collaboration),Volume I: Introduction to DUNE,JINST15(2020) T08008

    B. Abiet al.(DUNE Collaboration),Volume I: Introduction to DUNE,JINST15(2020) T08008

  34. [34]

    National Nuclear Data Center (NNDC),NuDat 3.0 Database, retrieved 03/19/2026

  35. [35]

    Adeyet al.(Daya Bay Collaboration),A high precision calibration of the nonlinear energy response at Daya Bay,Nucl

    D. Adeyet al.(Daya Bay Collaboration),A high precision calibration of the nonlinear energy response at Daya Bay,Nucl. Instrum. Meth. A940(2019) 230. – 16 –

  36. [36]

    Belliniet al.(Borexino Collaboration),New experimental limits on the Pauli-forbidden transitions in 12Cnuclei obtained with485days Borexino data,Phys

    G. Belliniet al.(Borexino Collaboration),New experimental limits on the Pauli-forbidden transitions in 12Cnuclei obtained with485days Borexino data,Phys. Rev. C81(2010) 034317

  37. [37]

    J. B. Albertet al.(EXO-200 Collaboration),Search for Majorana neutrinos with the first two years of EXO-200 data,Nature510(2014) 229

  38. [38]

    Andriamiradoet al.(PROSPECT Collaboration),Improved short-baseline neutrino oscillation search and energy spectrum measurement with the PROSPECT experiment at HFIR,Phys

    M. Andriamiradoet al.(PROSPECT Collaboration),Improved short-baseline neutrino oscillation search and energy spectrum measurement with the PROSPECT experiment at HFIR,Phys. Rev. D 103(2021) 032001

  39. [39]

    National Institute of Standards and Technology (NIST),XCOM: Photon Cross Sections Database, retrieved 03/19/2026

  40. [40]

    Acciarriet al.(MicroBooNE Collaboration),Design and construction of the MicroBooNE detector,JINST12(2017) P02017

    R. Acciarriet al.(MicroBooNE Collaboration),Design and construction of the MicroBooNE detector,JINST12(2017) P02017

  41. [41]

    Acciarriet al.(MicroBooNE Collaboration),Noise Characterization and Filtering in the MicroBooNE Liquid Argon TPC,JINST12(2017) P08003

    R. Acciarriet al.(MicroBooNE Collaboration),Noise Characterization and Filtering in the MicroBooNE Liquid Argon TPC,JINST12(2017) P08003

  42. [42]

    MicroBooNE Collaboration,A Measurement of the Attenuation of Drifting Electrons in the MicroBooNE LArTPC, MICROBOONE-NOTE-1026-PUB

  43. [43]

    Adamset al.(MicroBooNE Collaboration),Ionization electron signal processing in single phase LArTPCs

    C. Adamset al.(MicroBooNE Collaboration),Ionization electron signal processing in single phase LArTPCs. Part I. Algorithm Description and quantitative evaluation with MicroBooNE simulation, JINST13(2018) P07006

  44. [44]

    The Gund Company,NEMA Grade G-10 Glass Epoxy Laminate, retrieved 03/19/2026

  45. [45]

    E. L. Snider and G. Petrillo,LArSoft: toolkit for simulation, reconstruction and analysis of liquid argon TPC neutrino detectors,J. Phys.: Conf. Ser.898(2017) 042057

  46. [46]

    Agostinelliet al.,Geant4—a simulation toolkit,Nucl

    S. Agostinelliet al.,Geant4—a simulation toolkit,Nucl. Instrum. Meth. A506(2003) 250

  47. [47]

    Adamset al.(MicroBooNE Collaboration),Ionization electron signal processing in single phase LArTPCs

    C. Adamset al.(MicroBooNE Collaboration),Ionization electron signal processing in single phase LArTPCs. Part II. Data/simulation comparison and performance in MicroBooNE,JINST13(2018) P07007

  48. [48]

    Baller,Liquid argon TPC signal formation, signal processing and reconstruction techniques, JINST12(2017) P07010

    B. Baller,Liquid argon TPC signal formation, signal processing and reconstruction techniques, JINST12(2017) P07010. – 17 –