Snowmass Instrumentation Frontier IF08 Topical Group Report: Noble Element Detectors

Particle detectors making use of noble elements in gaseous, liquid, or solid phases are prevalent in neutrino and dark matter experiments and are also used to a lesser extent in collider-based particle physics experiments. These experiments take advantage of both the very large, ultra-pure target volumes achievable and the multiple observable signal pathways possible in noble-element based particle detectors. As these experiments seek to increase their sensitivity, novel and improved technologies will be needed to enhance the precision of their measurements and to broaden the reach of their physics programs. The areas of R&D in noble element instrumentation that have been identified by the HEP community in the Snowmass process are highlighted by five key messages: IF08-1) Enhance and combine existing modalities (scintillation and electron drift) to increase signal-to-noise and reconstruction fidelity; IF08-2) Develop new modalities for signal detection in noble elements, including methods based on ion drift, metastable fluids, solid-phase detectors and dissolved targets. Collaborative and blue-sky R&D should also be supported to enable advances in this area; IF08-3) Improve the understanding of detector microphysics and calibrate detector response in new signal regimes; IF08-4) Address challenges in scaling technologies, including material purification, background mitigation, large-area readout, and magnetization; and IF08-5) Train the next generation of researchers, using fast-turnaround instrumentation projects to provide the design-through-result training no longer possible in very-large-scale experiments. This topical group report identifies and documents recent developments and future needs for noble element detector technologies. In addition, we highlight the opportunity that this area of research provides for continued training of the next generation of scientists.Particle detectors making use of noble elements in gaseous, liquid, or solid phases are prevalent in neutrino and dark matter experiments and are also used to a lesser extent in collider-based particle physics experiments. These experiments take advantage of both the very large, ultra-pure target volumes achievable and the multiple observable signal pathways possible in noble-element based particle detectors. As these experiments seek to increase their sensitivity, novel and improved technologies will be needed to enhance the precision of their measurements and to broaden the reach of their physics programs. The areas of R&D in noble element instrumentation that have been identified by the HEP community in the Snowmass whitepapers and Community Summer Study are highlighted by five key messages: IF08-1) Enhance and combine existing modalities (scintillation and electron drift) to increase signal-to-noise and reconstruction fidelity; IF08-2) Develop new modalities for signal detection in noble elements, including methods based on ion drift, metastable fluids, solid-phase detectors and dissolved targets. Collaborative and blue-sky R&D should also be supported to enable advances in this area; IF08-3) Improve the understanding of detector microphysics and calibrate detector response in new signal regimes; IF08-4) Address challenges in scaling technologies, including material purification, background mitigation, large-area readout, and magnetization; and IF08-5) Train the next generation of researchers, using fast-turnaround instrumentation projects to provide the design-through-result training no longer possible in very-large-scale experiments. This topical group report identifies and documents recent developments and future needs for noble element detector technologies. In addition, we highlight the opportunity that this area of research provides for continued training of the next generation of scientists. detector technologies. In addition, we highlight the opportunities that this area of research provides for continued training of the next generation of scientists.

[1]  K. Nikolopoulos,et al.  The NEWS-G detector at SNOLAB , 2022, 2205.15433.

[2]  J. Zennamo,et al.  Xenon-doped liquid argon TPCs as a neutrinoless double beta decay platform , 2022, Physical Review D.

[3]  D. Nygren,et al.  Enhanced low-energy supernova burst detection in large liquid argon time projection chambers enabled by Q-Pix , 2022, Physical Review D.

[4]  K. Mahn,et al.  Bubble Chamber Detectors with Light Nuclear Targets: A Snowmass 2021 White Paper , 2022, 2203.11319.

[5]  W. Bonivento,et al.  A Facility for Low-Radioactivity Underground Argon , 2022, 2203.09734.

[6]  J. Zennamo,et al.  Low Background kTon-Scale Liquid Argon Time Projection Chambers , 2022, 2203.08821.

[7]  S. Vahsen,et al.  Snowmass2021 Cosmic Frontier Dark Matter Direct Detection to the Neutrino Fog , 2022, 2203.08084.

[8]  J. Beacom,et al.  SoLAr: Solar Neutrinos in Liquid Argon , 2022, 2203.07501.

[9]  A. Goldschmidt,et al.  Neutral Bremsstrahlung Emission in Xenon Unveiled , 2022, Physical Review X.

[10]  C. Conde,et al.  Dual-Polarity Ion Drift Chamber: A new system to measure the mobility of positive and negative ions , 2022, Nuclear Instruments and Methods in Physics Research Section A: Accelerators, Spectrometers, Detectors and Associated Equipment.

[11]  A. A. Denisenko,et al.  Ba ion trapping by organic submonolayer: towards an ultra-low background neutrinoless double beta decay detector , 2022 .

[12]  F. Toschi,et al.  Prospects of charge signal analyses in liquid xenon TPCs with proportional scintillation in the liquid phase , 2021, Journal of Instrumentation.

[13]  N. Bell,et al.  Observing the Migdal effect from nuclear recoils of neutral particles with liquid xenon and argon detectors , 2021, Physical Review D.

[14]  S. Schönert,et al.  Scintillation and optical properties of xenon-doped liquid argon , 2021, Journal of Instrumentation.

[15]  A. Buzulutskov,et al.  Neutral bremsstrahlung electroluminescence in noble liquids , 2021, Europhysics Letters.

[16]  K. Ni,et al.  Performance of a radial time projection chamber with electroluminescence in liquid xenon , 2021, Journal of Instrumentation.

[17]  A. A. Denisenko,et al.  The dynamics of ions on phased radio-frequency carpets in high pressure gases and application for barium tagging in xenon gas time projection chambers , 2021, Nuclear Instruments and Methods in Physics Research Section A: Accelerators, Spectrometers, Detectors and Associated Equipment.

[18]  K. Nikolopoulos,et al.  Quenching factor measurements of neon nuclei in neon gas , 2021, Physical Review D.

[19]  S. Pereverzev Detecting low-energy interactions and the effects of energy accumulation in materials , 2021, Physical Review D.

[20]  Tokyo,et al.  DARWIN – a next-generation liquid xenon observatory for dark matter and neutrino physics , 2021, Proceedings of 37th International Cosmic Ray Conference — PoS(ICRC2021).

[21]  A. Flammini,et al.  Direct comparison of PEN and TPB wavelength shifters in a liquid argon detector , 2021, The European Physical Journal C.

[22]  C. Dionisi,et al.  Performance of the ReD TPC, a novel double-phase LAr detector with silicon photomultiplier readout , 2021, The European Physical Journal C.

[23]  D. Nygren,et al.  First principles studies of the surface and opto-electronic properties of ultra-thin t-Se , 2021, 2104.14455.

[24]  J. I. Crespo-Anad'on,et al.  Deep Underground Neutrino Experiment (DUNE) Near Detector Conceptual Design Report , 2021, Instruments.

[25]  M. Clark,et al.  Correlated single- and few-electron backgrounds milliseconds after interactions in dual-phase liquid xenon time projection chambers , 2021, Journal of Instrumentation.

[26]  M. Rooks,et al.  Wavelength-shifting performance of polyethylene naphthalate films in a liquid argon environment , 2021, Journal of Instrumentation.

[27]  M. Mooney,et al.  A Review of Basic Energy Reconstruction Techniques in Liquid Xenon and Argon Detectors for Dark Matter and Neutrino Physics Using NEST , 2021, Instruments.

[28]  P. Giampa The Scintillating Bubble Chamber (SBC) Experiment for Dark Matter and Reactor CEvNS , 2021, Proceedings of 40th International Conference on High Energy physics — PoS(ICHEP2020).

[29]  A. A. Denisenko,et al.  Demonstration of Selective Single-Barium Ion Detection with Dry Diazacrown Ether Naphthalimide Turn-on Chemosensors. , 2021, ACS sensors.

[30]  E. Segreto Properties of liquid argon scintillation light emission , 2020, 2012.06527.

[31]  A. Rappoldi,et al.  Overhaul and installation of the ICARUS-T600 liquid argon TPC electronics for the FNAL Short Baseline Neutrino program , 2020, Journal of Instrumentation.

[32]  Y. Wang,et al.  Pulse shape study of the fast scintillation light emitted from xenon-doped liquid argon using silicon photomultipliers , 2020, Journal of Instrumentation.

[33]  P. Wilson,et al.  Demonstration of neutron radiation-induced nucleation of supercooled water. , 2018, Physical chemistry chemical physics : PCCP.

[34]  P. Barrillon,et al.  Separating 39 Ar from 40 Ar by cryogenic distillation with Aria for dark-matter searches , 2021 .

[35]  A. Szelc,et al.  Wavelength Shifters for Applications in Liquid Argon Detectors , 2020, Instruments.

[36]  R. Gibbons,et al.  Understanding the enhancement of scintillation light in xenon-doped liquid argon , 2020, Nuclear Instruments and Methods in Physics Research Section A: Accelerators, Spectrometers, Detectors and Associated Equipment.

[37]  F. Capasso,et al.  Improving the light collection efficiency of silicon photomultipliers through the use of metalenses , 2020, Journal of Instrumentation.

[38]  Fluorescent bicolour sensor for low-background neutrinoless double β decay experiments , 2020, Nature.

[39]  C. R. Hall,et al.  Investigation of background electron emission in the LUX detector , 2020, Physical Review D.

[40]  J. I. Crespo-Anad'on,et al.  Construction of precision wire readout planes for the Short-Baseline Near Detector (SBND) , 2020, Journal of Instrumentation.

[41]  J. Asaadi,et al.  Enhancing neutrino event reconstruction with pixel-based 3D readout for liquid argon time projection chambers , 2019, Journal of Instrumentation.

[42]  R. Nichol,et al.  The Liquid Argon In A Testbeam (LArIAT) experiment , 2019, Journal of Instrumentation.

[43]  J. P. Rodrigues,et al.  The LUX-ZEPLIN (LZ) experiment , 2019, Nuclear Instruments and Methods in Physics Research Section A: Accelerators, Spectrometers, Detectors and Associated Equipment.

[44]  A. Étenko,et al.  First ground-level laboratory test of the two-phase xenon emission detector RED-100 , 2019, Journal of Instrumentation.

[45]  T. Koffas,et al.  Design of a multiple-reflection time-of-flight mass spectrometer for barium-tagging , 2019, Hyperfine Interactions.

[46]  V. Belov,et al.  Fast component re-emission in Xe-doped liquid argon , 2019, Journal of Instrumentation.

[47]  A. A. Denisenko,et al.  Barium Chemosensors with Dry-Phase Fluorescence for Neutrinoless Double Beta Decay , 2019, Scientific Reports.

[48]  Y. H. Lin,et al.  Imaging individual barium atoms in solid xenon for barium tagging in nEXO , 2018, Nature.

[49]  D. Nygren,et al.  Q-Pix: Pixel-scale Signal Capture for Kiloton Liquid Argon TPC Detectors: Time-to-Charge Waveform Capture, Local Clocks, Dynamic Networks , 2018, 1809.10213.

[50]  D. Gnani,et al.  LArPix: demonstration of low-power 3D pixelated charge readout for liquid argon time projection chambers , 2018, Journal of Instrumentation.

[51]  B. Jones,et al.  Mobility and clustering of barium ions and dications in high-pressure xenon gas , 2018, Physical Review A.

[52]  A. V. Sokolov,et al.  Revealing neutral bremsstrahlung in two-phase argon electroluminescence , 2018, Astroparticle Physics.

[53]  G. B. Suffritti,et al.  Low-Mass Dark Matter Search with the DarkSide-50 Experiment. , 2018, Physical review letters.

[54]  L. M. Moutinho,et al.  Demonstration of Single-Barium-Ion Sensitivity for Neutrinoless Double-Beta Decay Using Single-Molecule Fluorescence Imaging. , 2017, Physical Review Letters.

[55]  C. Piemonte,et al.  DarkSide-20k: A 20 tonne two-phase LAr TPC for direct dark matter detection at LNGS , 2017, The European Physical Journal Plus.

[56]  M. Ibe,et al.  Migdal effect in dark matter direct detection experiments , 2017, Journal of High Energy Physics.

[57]  C. J. Chen,et al.  First Demonstration of a Scintillating Xenon Bubble Chamber for Detecting Dark Matter and Coherent Elastic Neutrino-Nucleus Scattering. , 2017, Physical review letters.

[58]  D. A. Wickremasinghe,et al.  Design and Construction of the MicroBooNE Detector , 2016, 1612.05824.

[59]  V. Belov,et al.  Study of Xe-doping to LAr scintillator , 2017 .

[60]  S. Gollapinni,et al.  Construction and assembly of the wire planes for the MicroBooNE Time Projection Chamber , 2016, 1609.06169.

[61]  B. Jones,et al.  Single molecule fluorescence imaging as a technique for barium tagging in neutrinoless double beta decay , 2016, 1609.04019.

[62]  D. Nygren Detection of the barium daughter in 136 Xe → 136 Ba+2e - by in situ single-molecule fluorescence imaging , 2016 .

[63]  M. Wójcik Electron recombination in low-energy nuclear recoils tracks in liquid argon , 2015, 1511.04300.

[64]  J. Wieser,et al.  Intense vacuum ultraviolet and infrared scintillation of liquid Ar-Xe mixtures , 2015, 1511.07723.

[65]  D. Tosi,et al.  An RF-only ion-funnel for extraction from high-pressure gases , 2014, 1412.1144.

[66]  Y. H. Lin,et al.  Spectroscopy of Ba and Ba + deposits in solid xenon for barium tagging in nEXO , 2014, 1410.2624.

[67]  Y. H. Lin,et al.  An apparatus to manipulate and identify individual Ba ions from bulk liquid Xe. , 2014, The Review of scientific instruments.

[68]  D. Mckinsey,et al.  Pulse-shape discrimination and energy resolution of a liquid-argon scintillator with xenon doping , 2014, 1403.0525.

[69]  I. Giomataris,et al.  NEWS : a new spherical gas detector for very low mass WIMP detection , 2014, 1401.7902.

[70]  M. Titov Perspectives of Micro-Pattern Gaseous Detector Technologies for Future Physics Projects , 2013, 1308.3047.

[71]  C. Bromberg,et al.  The ArgoNeuT Detector in the NuMI Low-Energy beam line at Fermilab , 2012, 1205.6747.

[72]  M. Auger,et al.  The EXO-200 detector, part I: detector design and construction , 2012, 1202.2192.

[73]  P. Peiffer,et al.  Pulse shape analysis of scintillation signals from pure and xenon-doped liquid argon for radioactive background identification , 2008 .

[74]  P. Colas,et al.  A Novel large-volume Spherical Detector with Proportional Amplification read-out , 2008, 0807.2802.

[75]  P. Fierlinger,et al.  A Linear RFQ Ion Trap for the Enriched Xenon Observatory , 2007, 0704.1646.

[76]  A. Bondar,et al.  Two-phase argon and xenon avalanche detectors based on Gas Electron Multipliers , 2005, physics/0510266.

[77]  J. White,et al.  SIGN, a WIMP Detector Based on High Pressure Gaseous Neon , 2006 .

[78]  G. Bonvicini,et al.  Negative ion drift and diffusion in a TPC near 1 bar , 2004, physics/0406114.

[79]  S. Amerio,et al.  Design, construction and tests of the ICARUS T600 detector , 2004 .

[80]  S. Dardin,et al.  Studies of electron avalanche behavior in liquid argon , 2001, 2001 IEEE Nuclear Science Symposium Conference Record (Cat. No.01CH37310).

[81]  M. Lehner,et al.  Suppressing drift chamber diffusion without magnetic field , 2000 .

[82]  Hitachi,et al.  Scintillation and ionization in allene-doped liquid argon irradiated with 18O and 36Ar ions of 30 MeV/u. , 1996, Physical review. B, Condensed matter.

[83]  M. Negrini,et al.  Improving the performance of the liquid argon TPC by doping with tetra-methyl-germanium , 1995 .

[84]  M. Cambiaghi,et al.  Electron multiplication in liquid argon on a tip array , 1991 .

[85]  H. Matsui,et al.  Energy resolution for 1 MeV electrons in liquid argon doped with allene , 1990 .

[86]  A. Hitachi,et al.  Energy resolution for alpha particles in liquid argon doped with allene , 1989 .

[87]  S. Suzuki,et al.  Photoionization in liquid argon doped with trimethylamine or triethylamine , 1986 .

[88]  S. Kubota,et al.  Estimation of Fano factors in liquid argon, krypton, xenon and xenon-doped liquid argon , 1976 .

[89]  A Gaseous Argon-Based Near Detector to Enhance the Physics Capabilities of DUNE , 2022, 2203.06281.