Your search keyword '"De Gerone M"' showing total 24 results

1. Status of the HOLMES Experiment

Author

De Gerone, M., Alpert, B., Balata, M., Becker, D. T., Bennett, D. A., Bevilacqua, A., Borghesi, M., Ceruti, G., De Galembert, G. De Bodin, Dressler, R., Faverzani, M., Fedkevych, M., Ferri, E., Fowler, J. W., Gallucci, G., Gard, J. D., Gatti, F., Giachero, A., Hilton, G. C., Köster, U., Lusignoli, M., Manfrinetti, P., Mates, J. A. B., Maugeri, E., Nisi, S., Nucciotti, A., Parodi, L., Pessina, G., Ragazzi, S., Reintsema, C. D., Schmidt, D. R., Schumann, D., Siccardi, F., Swetz, D. S., Ullom, J. N., and Vale, L. R.

Published

2022

2. Transition-Edge Sensors for HOLMES

Author

Puiu, A., Becker, D., Bennett, D., Biasotti, M., Borghesi, M., De Gerone, M., Faverzani, M., Ferri, E., Fowler, J., Gallucci, G., Gard, J., Gatti, F., Hilton, G., Giachero, A., Mates, J., Nucciotti, A., Pessina, G., Schmidt, D., Swetz, D., Ullom, J., and Vale, L.

Published

2020

3. Status of the HOLMES Experiment

Author

Faverzani, M., Alpert, B., Balata, M., Backer, D., Bennet, D., Bevilaqua, A., Biasotti, M., Borghesi, M., Ceruti, G., De Gerone, M., Dressler, R., Ferri, E., Fowler, J., Gallucci, G., Gard, J., Gatti, F., Giachero, A., Heinitz, S., Hilton, G., Köster, U., Lusignoli, M., Mates, J., Maugeri, E., Nisi, S., Nucciotti, A., Parodi, L., Pessina, G., Puiu, A., Ragazzi, S., Reintsema, C., Ribeiro-Gomez, M., Schmidt, D., Schumann, D., Siccardi, F., Swetz, D., Ullom, J., and Vale, L.

Published

2020

4. Status of the HOLMES Experiment to Directly Measure the Neutrino Mass

Author

Nucciotti, A., Alpert, B., Balata, M., Becker, D., Bennett, D., Bevilacqua, A., Biasotti, M., Ceriale, V., Ceruti, G., Corsini, D., De Gerone, M., Dressler, R., Faverzani, M., Ferri, E., Fowler, J., Gallucci, G., Gard, J., Gatti, F., Giachero, A., Hays-Wehle, J., Heinitz, S., Hilton, G., Köster, U., Lusignoli, M., Mates, J., Nisi, S., Orlando, A., Parodi, L., Pessina, G., Puiu, A., Ragazzi, S., Reintsema, C., Ribeiro-Gomez, M., Schmidt, D., Schuman, D., Siccardi, F., Swetz, D., Ullom, J., and Vale, L.

Published

2018

5. The HOLMES Experiment

Author

Faverzani, M., Alpert, B., Backer, D., Bennet, D., Biasotti, M., Brofferio, C., Ceriale, V., Ceruti, G., Corsini, D., Day, P. K., De Gerone, M., Dressler, R., Ferri, E., Fowler, J., Fumagalli, E., Gard, J., Gatti, F., Giachero, A., Hays-Wehle, J., Heinitz, S., Hilton, G., Köster, U., Lusignoli, M., Maino, M., Mates, J., Nisi, S., Nizzolo, R., Nucciotti, A., Orlando, A., Parodi, L., Pessina, G., Pizzigoni, G., Puiu, A., Ragazzi, S., Reintsema, C., Ribeiro-Gomez, M., Schmidt, D., Schuman, D., Siccardi, F., Sisti, M., Swetz, D., Terranova, F., Ullom, J., and Vale, L.

Published

2016

6. Commissioning of the Ion Implanter for the HOLMES Experiment.

Author

De Gerone, M., Bevilacqua, A., Biasotti, M., Borghesi, M., Cerboni, N., Ceruti, G., De Bodin De Galembert, G., Faverzani, M., Fedkevych, M., Ferri, E., Gallucci, G., Gatti, F., Giachero, A., Lo Cicero, A., Maugeri, E., Manfrinetti, P., Nucciotti, A., Parodi, L., Pessina, G., and Pollovio, P.

Subjects

*NEUTRON irradiation, *ELECTRON capture, *CHEMICAL processes, *ION implantation, *ION sources, *MAGNETIC dipoles, *BETA decay

Abstract

The HOLMES experiment aims to directly measure the ν mass studying the 163 Ho electron capture decay spectrum developing arrays of TES-based microcalorimeters implanted with O(300 Bq/detector) Ho atoms. The embedding of the source inside detectors is a crucial step of the experiment. Because the 163 Ho production process (neutron irradiation of a 162 Er sample) is not perfectly free from impurities, Ho source must be separated from a lot of contaminants. A chemical processing removes every species other than Ho, but it is not sufficient to remove all isotope-related background sources: Indeed, 166 m Ho beta decay can produce fake signal in the region of interest. For this reason, a dedicated implantation system was set up. It is designed to achieve the separation power better than 5 σ at 163/166 a.m.u. allowing an efficient Ho ions implantation inside microcalorimeter absorbers. Its main components are a 50 kV sputter-based ion source, a magnetic dipole and a target chamber. A specially designed co-evaporation system was designed to "grow" the gold microcalorimeter absorber during the implantation process, increasing the maximum achievable activity which can be implanted. The machine performances were evaluated by means of calibration runs using 63 Cu/ 65 Cu and Mo beams. A special care was given to the study of the more effective way to populate source plasma with Ho ions obtained from different Ho compounds by sputtering process. In this work, the machine development and commissioning are described. [ABSTRACT FROM AUTHOR]

Published

2022

7. Progress in the Development of TES Microcalorimeter Detectors Suitable for Neutrino Mass Measurement.

Author

Giachero, Andrea, Alpert, Bradley, Becker, D.T., Bennett, D.A., Borghesi, M., De Gerone, M., Faverzani, M., Fedkevych, M., Ferri, E., Gallucci, G., Gard, J.D., Gatti, F., Hilton, G.C., Mates, J.A.B., Nucciotti, A., Pessina, G., Puiu, A., Reintsema, C.D., Schmidt, D.R., and Swetz, D.S.

Subjects

NEUTRINO mass, MASS measurement, ELECTRON capture, NUCLEAR counters, NEUTRINOS, MICROWAVE devices, SOLAR neutrinos

Abstract

The HOLMES experiment will perform a precise calorimetric measurement of the end point of the Electron Capture (EC) decay spectrum of 163Ho in order to extract information on neutrino mass with a sensitivity below 2 eV. In its final configuration, HOLMES will deploy 1000 detectors of low temperature microcalorimeters with implanted 163Ho nuclei. The baseline sensors for HOLMES are Mo/Cu TESs (Transition Edge Sensors) on SiNx membrane with gold absorbers. Considering the large number of pixels and an event rate of about 300 Hz/pixel, a large multiplexing factor and a large bandwidth are needed. To fulfill this requirement, HOLMES will exploit recent advances on microwave multiplexing. In this contribution we present the status of the activities in development, the performances of the developed microwave-multiplexed readout system, and the results obtained with the detectors specifically designed for HOLMES in terms of noise, time and energy resolutions. [ABSTRACT FROM AUTHOR]

Published

2021

8. Updates on the Transition-Edge Sensors and Multiplexed Readout for HOLMES.

Author

Puiu, A., Becker, D., Bennett, D., Biasotti, M., Borghesi, M., Ceriale, V., De Gerone, M., Faverzani, M., Ferri, E., Fowler, J., Gallucci, G., Gard, J., Hays-Wehle, J., Hilton, G., Giachero, A., Mates, J., Nucciotti, A., Orlando, A., Pessina, G., and Schmidt, D.

Subjects

NEUTRINO mass, PARTICLE physics, ELECTRON capture, RADIOACTIVE decay, THERMOMETERS

Abstract

Measuring the neutrino mass is one of the most compelling issues in particle physics. HOLMES is an experiment for a direct measurement of the neutrino mass. HOLMES will perform a precise measurement of the end point of the electron capture decay spectrum of 163Ho in order to extract information on the neutrino mass with a sensitivity as low as 1 eV. HOLMES, in its final configuration, will deploy a 1000-pixel array of low-temperature microcalorimeters: each calorimeter is made of an absorber, where the Ho atoms will be implanted, coupled to a transition-edge sensor (TES) thermometer. The detectors will be operated at the working temperature of 100mK provided by a dilution refrigerator. In order to read out the 1000-detector array of HOLMES, a multiplexing system is necessary: the choice is to couple the transition-edge sensors to a multiplexed rf-SQUID. In this contribution we outline the progress made towards the final configuration of HOLMES regarding both the performances of the TES detectors and the characteristics of the multiplexing system. [ABSTRACT FROM AUTHOR]

Published

2018

9. Development and commissioning of the ion implanter for the HOLMES experiment.

Author

De Gerone, M., Bevilacqua, A., Borghesi, M., Cerboni, N., Ceruti, G., De Bodin De Galembert, G., Faverzani, M., Fedkevych, M., Ferri, E., Gallucci, G., Gatti, F., Giachero, A., Maugeri, E., Manfrinetti, P., Nucciotti, A., Parodi, L., Pessina, G., Ragazzi, S., Schumann, D., and Siccardi, F.

Subjects

*CHEMICAL processes, *ION sources, *ELECTRON capture, *NEUTRON irradiation, *RADIOISOTOPES, *MAGNETIC dipoles

Abstract

The HOLMES experiment aims to directly measure the ν mass studying the 163Ho electron capture decay spectrum, using arrays of TES-based micro-calorimeters implanted with O(102 Bq/detector) 163Ho atoms. The neutron irradiation of 162Er enriched samples, used for the production of 163Ho, also generates radioactive contaminants. Chemical processes have been developed to extract the Ho fraction with high efficiency. The radioactive Ho isotope 166 m Ho is also present in the final sample and could significantly contribute to background events in the final spectrum. For this reason a dedicated implantation/mass separator has been set up and commissioned. It is designed to achieve more than 5 σ separation 163/166 u simultaneously allowing an efficient 163Ho atoms embedding inside micro-calorimeter absorbers. Its main components are a 50 kV sputter-based ion source, a magnetic dipole and a target chamber. A specially designed co-evaporation system has been implemented to deposit gold on the detector absorbers during implantation to overcome the 163Ho source saturation problem. The system performances in terms of achievable beam current, profile and mass separation have been evaluated by means of calibration runs using Cu, Mo, Au and 165Ho beams. An intensive study was done to optimize the target containing 163Ho in order to achieve a large fraction of ionized Ho in the beam. In this work, the machine development and commissioning will be described. [ABSTRACT FROM AUTHOR]

Published

2023

10. Probing the absolute neutrino mass scale with 163Ho: The HOLMES project.

Author

De Gerone, M., Alpert, B., Becker, D., Bennett, D., Biasotti, M., Ceriale, V., Dressler, R., Faverzani, M., Ferri, E., Fowler, J., Gallucci, G., Gard, J., Gatti, F., Giachero, A., Hays-Wehle, J., Heinitz, S., Hilton, G., Koester, U., Lusignoli, M., and Mates, J.

Subjects

*NEUTRINO mass, *ELECTRON capture, *MASS measurement

Abstract

The HOLMES project aims to directly measure the ν mass down to the eV scale using the electron capture decay (EC) of 163Ho. It will perform a precise calorimetric measurement of the end-point of the Ho energy spectrum looking for the deformation caused by a finite ν mass. The choice of 163Ho as source is driven by the very low Q-value of the EC reaction, which allows for high sensitivity with low activities (O(10 2)Bq/detector), thus reducing the pile-up probability. A large array made by thousands of transition edge sensors based micro-calorimeters will be used. The calorimetric approach eliminates systematic uncertainties arising from the use of an external β source, and minimizes the effect of the atomic de-excitation process. The commissioning of the first implanted sub-array is scheduled for the end of 2018. It will provide useful data about the EC decay of 163Ho together with a first limit on ν mass. [ABSTRACT FROM AUTHOR]

Published

2019

11. High-resolution high-speed microwave-multiplexed low temperature microcalorimeters for the HOLMES experiment.

Author

Alpert, B., Becker, D., Bennet, D., Biasotti, M., Borghesi, M., Gallucci, G., De Gerone, M., Faverzani, M., Ferri, E., Fowler, J., Gard, J., Giachero, A., Hays–Wehle, J., Hilton, G., Mates, J., Nucciotti, A., Orlando, A., Pessina, G., Puiu, A., and Reintsema, C.

Subjects

LOW temperatures, CALORIMETERS, ELECTRON capture, NEUTRINO mass, COSMIC background radiation

Abstract

We present the first performance results obtained with microwave multiplexed Transition Edge Sensors prototypes specifically designed for the HOLMES experiment, a project aimed at directly measuring the electron neutrino mass through the calorimetric measurement of the 163 Ho electron capture spectrum. The detectors required for such an experiment feature a high energy resolution at the Q–value of the transition, around ∼ 2.8 keV, and a fast response time combined with the compatibility to be multiplexed in large arrays in order to collect a large statistics while keeping the pile-up contribution as small as possible. In addition, the design has to be suitable for future ion-implantation of 163 Ho. The results obtained in these tests allowed us to identify the optimal detector design among several prototypes. The chosen detector achieved an energy resolution of (4.5 ± 0.3) eV on the chlorine K α line, at ∼ 2.6 keV, obtained with an exponential rise time of 14 μ s. The achievements described in this paper pose a milestone for the HOLMES detectors, setting a baseline for the subsequent developments, aiming to the actual ion-implantation of the 163 Ho nuclei. In the first section the HOLMES experiment is outlined along with its physics goal, while in the second section the HOLMES detectors are described; the experimental set-up and the calibration source used for the measurements described in this paper are reported in Sects. 3 and 4, respectively; finally, the details of the data analysis and the results obtained are reported in Sect. 6. [ABSTRACT FROM AUTHOR]

Published

2019

12. Progress in the development of TES microcalorimeter detectors suitable for neutrino mass measurement

Author

Dan Becker, Daniel S. Swetz, A. Nucciotti, Gene C. Hilton, M. De Gerone, Bradley K. Alpert, Andrea Giachero, Flavio Gatti, A. Puiu, G. Gallucci, Leila R. Vale, Johnathon D. Gard, G. Pessina, Joel N. Ullom, M. Borghesi, Douglas A. Bennett, Carl D. Reintsema, M. Fedkevych, D. R. Schmidt, M. Faverzani, John A. B. Mates, Emanuele Ferri, Giachero, A, Alpert, B, Becker, D, Bennett, D, Borghesi, M, De Gerone, M, Faverzani, M, Fedkevych, M, Ferri, E, Gallucci, G, Gard, J, Gatti, F, Hilton, G, Mates, J, Nucciotti, A, Pessina, G, Puiu, A, Reintsema, C, Schmidt, D, Swetz, D, Ullom, J, and Vale, L

Subjects

radiation detector, X-ray detector, Physics - Instrumentation and Detectors, Electron capture, Physics::Instrumentation and Detectors, superconducting microwave device, FOS: Physical sciences, superconducting microwave devices, SQUID, Elementary particle, 01 natural sciences, Multiplexing, Noise (electronics), Optics, radiation detectors, 0103 physical sciences, Electrical and Electronic Engineering, 010306 general physics, Physics, Pixel, business.industry, Bandwidth (signal processing), Detector, Elementary particles, X-ray detectors, Instrumentation and Detectors (physics.ins-det), Condensed Matter Physics, Electronic, Optical and Magnetic Materials, Neutrino, business, Microwave

Abstract

The HOLMES experiment will perform a precise calorimetric measurement of the end point of the Electron Capture (EC) decay spectrum of 163Ho in order to extract information on neutrino mass with a sensitivity below 2 eV. In its final configuration, HOLMES will deploy 1000 detectors of low-temperature microcalorimeters with implanted 163Ho nuclei. The baseline sensors for HOLMES are Mo/Cu TESs (Transition Edge Sensors) on SiNx membrane with gold absorbers. Considering the large number of pixels and an event rate of about 300 Hz/pixel, a large multiplexing factor and a large bandwidth are needed. To fulfill this requirement, HOLMES will exploit recent advances in microwave multiplexing. In this contribution, we present the status of the activities in development, the performances of the developed microwave-multiplexed readout system, and the results obtained with the detectors specifically designed for HOLMES in terms of noise, time, and energy resolutions

Published

2021

13. Transition-Edge Sensors for HOLMES

Author

D. A. Bennett, Gene C. Hilton, Michele Biasotti, Daniel Schmidt, Dan Becker, M. De Gerone, John A. B. Mates, A. Nucciotti, Andrea Giachero, Emanuele Ferri, M. Faverzani, Joseph W. Fowler, A. Puiu, Johnathon D. Gard, G. Gallucci, Joel N. Ullom, M. Borghesi, Leila R. Vale, G. Pessina, Daniel S. Swetz, Flavio Gatti, Puiu, A, Becker, D, Bennett, D, Biasotti, M, Borghesi, M, De Gerone, M, Faverzani, M, Ferri, E, Fowler, J, Gallucci, G, Gard, J, Gatti, F, Hilton, G, Giachero, A, Mates, J, Nucciotti, A, Pessina, G, Schmidt, D, Swetz, D, Ullom, J, and Vale, L

Subjects

Physics, Particle physics, Transition-edge sensors, Physics::Instrumentation and Detectors, Electron capture, RF-SQUID, Detector, Order (ring theory), HOLMES, Multiplexing, Condensed Matter Physics, 01 natural sciences, Atomic and Molecular Physics, and Optics, 010305 fluids & plasmas, 0103 physical sciences, General Materials Science, Sensitivity (control systems), Special care, Neutrino, 010306 general physics, Transition edge

Abstract

HOLMES is an experiment aiming at performing a direct measurement of the neutrino mass from the electron capture (EC) spectrum of $$^{163}\hbox {Ho}$$. In order to reach a sensitivity of the order of $$\sim $$1 eV/c$$^2$$ on the neutrino mass, it is necessary to gather as many as $$10^{13}$$ events in the 3-year projected live time of HOLMES, keeping the pileup fraction as low as $$10^{-4}$$. This is not a trivial matter when it comes to low- temperature calorimeters, which usually have a rather slow time response. At the same time, a large number of detectors need to be operated simultaneously, and hence, in order to avoid an extremely large cryogenic facility, multiplexing is required. In this contribution, I will outline the current status and perspective of HOLMES, with special care devoted to the detectors and readout system, which have currently reached their target performance.

Published

2020

14. Status of the HOLMES Experiment

Author

Joseph W. Fowler, M. Faverzani, M. Ribeiro-Gomez, Dorothea Schumann, Carl D. Reintsema, Daniel Schmidt, G. Gallucci, Evelyn Ferri, Ulli Köster, S. Ragazzi, F. Siccardi, A. Bevilaqua, Joel N. Ullom, M. Borghesi, L. Parodi, Stefano Nisi, M. Balata, A. Nucciotti, A. Puiu, John A. B. Mates, G. Ceruti, Emilio Andrea Maugeri, D. Bennet, D. Backer, Michele Biasotti, Bradley K. Alpert, M. De Gerone, Gene C. Hilton, Leila R. Vale, G. Pessina, Daniel S. Swetz, S. Heinitz, M. Lusignoli, Flavio Gatti, Andrea Giachero, Johnathon D. Gard, Rugard Dressler, Institut Laue-Langevin (ILL), ILL, Faverzani, M, Alpert, B, Balata, M, Backer, D, Bennet, D, Bevilaqua, A, Biasotti, M, Borghesi, M, Ceruti, G, De Gerone, M, Dressler, R, Ferri, E, Fowler, J, Gallucci, G, Gard, J, Gatti, F, Giachero, A, Heinitz, S, Hilton, G, Köster, U, Lusignoli, M, Mates, J, Maugeri, E, Nisi, S, Nucciotti, A, Parodi, L, Pessina, G, Puiu, A, Ragazzi, S, Reintsema, C, Ribeiro-Gomez, M, Schmidt, D, Schumann, D, Siccardi, F, Swetz, D, Ullom, J, and Vale, L

Subjects

Photon, experimental methods, Electron capture, Physics::Instrumentation and Detectors, electron: capture, Electron, 01 natural sciences, 7. Clean energy, HOLMES, 010305 fluids & plasmas, Nuclear physics, Neutrino mass, 0103 physical sciences, Atom, calorimeter, General Materials Science, Sensitivity (control systems), holmium: nuclide, neutrino: mass, [PHYS.PHYS.PHYS-INS-DET]Physics [physics]/Physics [physics]/Instrumentation and Detectors [physics.ins-det], 010306 general physics, Transition edge sensors, detector: design, activity report, Physics, Isotope, Condensed Matter Physics, sensitivity, Atomic and Molecular Physics, and Optics, pile-up, Excited state, High Energy Physics::Experiment, Neutrino, Neutrino ma, Transition edge sensor

Abstract

International audience; The absolute neutrino mass is still an unknown parameter in the modern landscape of particle physics. The HOLMES experiment aims at exploiting the calorimetric approach to directly measure the neutrino mass through the kinematic measurement of the decay products of the weak process decay of $^{163}$Ho. This low energy decaying isotope, in fact, undergoes electron capture emitting a neutrino and leaving the daughter atom, $^{163}$Dy$^*$, in an atomic excited state. This, in turn, relaxes by emitting electrons and, to a considerably lesser extent, photons. The high-energy portion of the calorimetric spectrum of this decay is affected by the non-vanishing neutrino mass value. Given the small fraction of events falling within the region of interest, to achieve a high experimental sensitivity on the neutrino mass, it is important to have a high activity combined with a very small undetected pileup contribution. To achieve these targets, the final configuration of HOLMES foresees the deployment of a large number of $^{163}$Ho ion-implanted TESs characterized by an ambitiously high activity of 300 Hz each. In this paper, we outline the status of the major tasks that will bring HOLMES to achieve a statistical sensitivity on the neutrino mass as low as 2 eV/c$^2$.

Published

2019

15. High-resolution high-speed microwave-multiplexed low temperature microcalorimeters for the HOLMES experiment

Author

Dan Becker, G. Gallucci, Michele Biasotti, Daniel S. Swetz, D. Bennet, Joel N. Ullom, M. Borghesi, Leila R. Vale, Joseph W. Fowler, G. Pessina, John A. B. Mates, Gene C. Hilton, Johnathon D. Gard, M. De Gerone, J. Hays–Wehle, Andrea Giachero, A. Puiu, Carl D. Reintsema, Daniel Schmidt, Angiola Orlando, Evelyn Ferri, Bradley K. Alpert, A. Nucciotti, M. Faverzani, Alpert, B, Becker, D, Bennet, D, Biasotti, M, Borghesi, M, Gallucci, G, De Gerone, M, Faverzani, M, Ferri, E, Fowler, J, Gard, J, Giachero, A, Hays–wehle, J, Hilton, G, Mates, J, Nucciotti, A, Orlando, A, Pessina, G, Puiu, A, Reintsema, C, Schmidt, D, Swetz, D, Ullom, J, and Vale, L

Subjects

Physics, Physics and Astronomy (miscellaneous), 010308 nuclear & particles physics, Electron capture, Detector, X-ray detector, Response time, lcsh:Astrophysics, 01 natural sciences, Exponential function, Computational physics, Rise time, lcsh:QB460-466, 0103 physical sciences, lcsh:QC770-798, lcsh:Nuclear and particle physics. Atomic energy. Radioactivity, X-ray detectors, neutrino physics, neutrino mass, 010306 general physics, Engineering (miscellaneous), Electron neutrino, Microwave

Abstract

We present the first performance results obtained with microwave multiplexed Transition Edge Sensors prototypes specifically designed for the HOLMES experiment, a project aimed at directly measuring the electron neutrino mass through the calorimetric measurement of the $$^{163}$$ Ho electron capture spectrum. The detectors required for such an experiment feature a high energy resolution at the Q–value of the transition, around $$\sim $$ 2.8 keV, and a fast response time combined with the compatibility to be multiplexed in large arrays in order to collect a large statistics while keeping the pile-up contribution as small as possible. In addition, the design has to be suitable for future ion-implantation of $$^{163}$$ Ho. The results obtained in these tests allowed us to identify the optimal detector design among several prototypes. The chosen detector achieved an energy resolution of (4.5 ± 0.3) eV on the chlorine K $$_\alpha $$ line, at $$\sim $$ 2.6 keV, obtained with an exponential rise time of 14 $$\upmu $$ s. The achievements described in this paper pose a milestone for the HOLMES detectors, setting a baseline for the subsequent developments, aiming to the actual ion-implantation of the $$^{163}$$ Ho nuclei. In the first section the HOLMES experiment is outlined along with its physics goal, while in the second section the HOLMES detectors are described; the experimental set-up and the calibration source used for the measurements described in this paper are reported in Sects. 3 and 4, respectively; finally, the details of the data analysis and the results obtained are reported in Sect. 6.

Published

2019

16. Probing the absolute neutrino mass scale with 163Ho: The HOLMES project

Author

Dan Becker, M. Ribeiro Gomes, Daniel Schmidt, M. Faverzani, Michele Biasotti, Joseph W. Fowler, G. Gallucci, Angelo Orlando, James P. Hays-Wehle, S. Nisi, Rugard Dressler, Carl D. Reintsema, Joel N. Ullom, A. Nucciotti, John A. B. Mates, Andrea Giachero, D. A. Bennett, Emanuele Ferri, Leila R. Vale, V. Ceriale, Daniel S. Swetz, M. Lusignoli, Flavio Gatti, Bradley K. Alpert, G. Pessina, U. Koester, S. Heinitz, A. Puiu, Dorothea Schumann, Gene C. Hilton, S. Ragazzi, Johnathon D. Gard, M. De Gerone, De Gerone, M, Alpert, B, Becker, D, Bennett, D, Biasotti, M, Ceriale, V, Dressler, R, Faverzani, M, Ferri, E, Fowler, J, Gallucci, G, Gard, J, Gatti, F, Giachero, A, Hays-Wehle, J, Heinitz, S, Hilton, G, Koester, U, Lusignoli, M, Mates, J, Nucciotti, A, Nisi, S, Orlando, A, Pessina, G, Puiu, A, Ragazzi, S, Reintsema, C, Ribeiro Gomes, M, Schmidt, D, Schumann, D, Swetz, D, Ullom, J, Vale, L, Institut Laue-Langevin (ILL), and ILL

Subjects

Nuclear and High Energy Physics, Scale (ratio), Electron capture, Instrumentation, electron: capture, 02 engineering and technology, 7. Clean energy, 01 natural sciences, Measure (mathematics), HOLMES, Nuclear physics, Holmium, 0103 physical sciences, calorimeter, holmium: nuclide, neutrino: mass, [PHYS.PHYS.PHYS-INS-DET]Physics [physics]/Physics [physics]/Instrumentation and Detectors [physics.ins-det], Sensitivity (control systems), 010306 general physics, Neutrino mass measurement, Transition edge sensors, activity report, Physics, Detector, sensitivity, 021001 nanoscience & nanotechnology, Calorimeter, pile-up, Neutrino, 0210 nano-technology, Transition edge sensor

Abstract

The HOLMES project aims to directly measure the ν mass down to the eV scale using the electron capture decay (EC) of 163Ho. It will perform a precise calorimetric measurement of the end-point of the Ho energy spectrum looking for the deformation caused by a finite ν mass. The choice of 163Ho as source is driven by the very low Q-value of the EC reaction, which allows for high sensitivity with low activities (O(10 2 )Bq/detector), thus reducing the pile-up probability. A large array made by thousands of transition edge sensors based micro-calorimeters will be used. The calorimetric approach eliminates systematic uncertainties arising from the use of an external β source, and minimizes the effect of the atomic de-excitation process. The commissioning of the first implanted sub-array is scheduled for the end of 2018. It will provide useful data about the EC decay of 163Ho together with a first limit on ν mass.

Published

2019

17. Status of the HOLMES Experiment to Directly Measure the Neutrino Mass

Author

A. Nucciotti, B. Alpert, M. Balata, D. Becker, D. Bennett, A. Bevilacqua, M. Biasotti, V. Ceriale, G. Ceruti, D. Corsini, M. De Gerone, R. Dressler, M. Faverzani, E. Ferri, J. Fowler, G. Gallucci, J. Gard, F. Gatti, A. Giachero, J. Hays-Wehle, S. Heinitz, G. Hilton, U. Köster, M. Lusignoli, J. Mates, S. Nisi, A. Orlando, L. Parodi, G. Pessina, A. Puiu, S. Ragazzi, C. Reintsema, M. Ribeiro-Gomez, D. Schmidt, D. Schuman, F. Siccardi, D. Swetz, J. Ullom, L. Vale, Nucciotti, A, Alpert, B, Balata, M, Becker, D, Bennett, D, Bevilacqua, A, Biasotti, M, Ceriale, V, Ceruti, G, Corsini, D, De Gerone, M, Dressler, R, Faverzani, M, Ferri, E, Fowler, J, Gallucci, G, Gard, J, Gatti, F, Giachero, A, Hays-Wehle, J, Heinitz, S, Hilton, G, Köster, U, Lusignoli, M, Mates, J, Nisi, S, Orlando, A, Parodi, L, Pessina, G, Puiu, A, Ragazzi, S, Reintsema, C, Ribeiro-Gomez, M, Schmidt, D, Schuman, D, Siccardi, F, Swetz, D, Ullom, J, Vale, L, Institut Laue-Langevin (ILL), and ILL

Subjects

detector: technology, experimental methods, Physics - Instrumentation and Detectors, Atomic and Molecular Physics, and Optic, Electron capture, Physics::Instrumentation and Detectors, Measure (physics), FOS: Physical sciences, electron: capture, [PHYS.NEXP]Physics [physics]/Nuclear Experiment [nucl-ex], 01 natural sciences, Cosmology, High Energy Physics - Experiment, Nuclear physics, High Energy Physics - Experiment (hep-ex), Holmium, Atomic and Molecular Physics, 0103 physical sciences, calorimeter, [PHYS.HEXP]Physics [physics]/High Energy Physics - Experiment [hep-ex], Transition Edge Sensors, General Materials Science, holmium: nuclide, neutrino: mass, [PHYS.PHYS.PHYS-INS-DET]Physics [physics]/Physics [physics]/Instrumentation and Detectors [physics.ins-det], Nuclear Experiment (nucl-ex), 010306 general physics, Absolute scale, Nuclear Experiment, activity report, Physics, 010308 nuclear & particles physics, Detector, Instrumentation and Detectors (physics.ins-det), Condensed Matter Physics, Atomic and Molecular Physics, and Optics, Excited state, Neutrino mass measurement, Transition edge sensors, Materials Science (all), High Energy Physics::Experiment, and Optics, Neutrino, Transition edge sensor, Energy (signal processing), FIS/04 - FISICA NUCLEARE E SUBNUCLEARE

Abstract

The assessment of neutrino absolute mass scale is still a crucial challenge in today particle physics and cosmology. Beta or electron capture spectrum end-point study is currently the only experimental method which can provide a model independent measurement of the absolute scale of neutrino mass. HOLMES is an experiment funded by the European Research Council to directly measure the neutrino mass. HOLMES will perform a calorimetric measurement of the energy released in the electron capture decay of the artificial isotope $^{163}$Ho. In a calorimetric measurement the energy released in the decay process is entirely contained into the detector, except for the fraction taken away by the neutrino. This approach eliminates both the issues related to the use of an external source and the systematic uncertainties arising from decays on excited final states. The most suitable detectors for this type of measurement are low temperature thermal detectors, where all the energy released into an absorber is converted into a temperature increase that can be measured by a sensitive thermometer directly coupled with the absorber. This measurement was originally proposed in 1982 by A. De Rujula and M. Lusignoli, but only in the last decade the technological progress in detectors development has allowed to design a sensitive experiment. HOLMES plans to deploy a large array of low temperature microcalorimeters with implanted $^{163}$Ho nuclei. In this contribution we outline the HOLMES project with its physics reach and technical challenges, along with its status and perspectives., This is a pre-print of an article published in Journal of Low Temperature Physics. The final authenticated version is available online at: https://doi.org/10.1007/s10909-018-2025-x

Published

2018

18. Direct neutrino mass measurement by the HOLMES experiment

Author

C. D. Reintsema, John A. B. Mates, A. Bevilacqua, Joseph W. Fowler, M. Faverzani, G. Pessina, Gene C. Hilton, S. Heinitz, Daniel Schmidt, A. Giachero, L. Parodi, J. N. Ullom, S. Ragazzi, D. Schuman, M. Balata, Angelo Orlando, Michele Biasotti, L. R. Vale, Bradley K. Alpert, Flavio Gatti, M. De Gerone, D. Corsini, Rugard Dressler, G. Ceruti, James P. Hays-Wehle, Evelyn Ferri, A. Puiu, Stefano Nisi, D. A. Bennett, A. Nucciotti, Ulli Köster, D. T. Becker, V. Ceriale, Daniel S. Swetz, J. D. Gard, M. Ribeiro-Gomez, M. Lusignoli, F. Siccardi, Institut Laue-Langevin (ILL), ILL, Nucciotti, A, Alpert, B, Balata, M, Becker, D, Bennett, D, Bevilacqua, A, Biasotti, M, Ceriale, V, Ceruti, G, Corsini, D, De Gerone, M, Dressler, R, Faverzani, M, Ferri, E, Fowler, J, Gard, J, Gatti, F, Giachero, A, Hays-Wehle, J, Heinitz, S, Hilton, G, Köster, U, Lusignoli, M, Mates, J, Nisi, S, Orlando, A, Parodi, L, Pessina, G, Puiu, A, Ragazzi, S, Reintsema, C, Ribeiro-Gomez, M, Schmidt, D, Schuman, D, Siccardi, F, Swetz, D, Ullom, J, and Vale, L

Subjects

History, cosmological model, experimental methods, Electron capture, Physics::Instrumentation and Detectors, data acquisition, energy resolution, electron: capture, [PHYS.NEXP]Physics [physics]/Nuclear Experiment [nucl-ex], Mass spectrometry, 01 natural sciences, Education, Nuclear physics, mass: scale, Physics and Astronomy (all), Data acquisition, temperature: low, pixel, n: irradiation, 0103 physical sciences, calorimeter, neutrino: mass, 010306 general physics, Absolute scale, time resolution, Physics, low temperature detector, Range (particle radiation), 010308 nuclear & particles physics, Detector, nucleus, 163-Ho, sensitivity, Computer Science Applications, Calorimeter, Automatic Keywords, ion, Neutrino, Neutrino ma, up: mass, TES, FIS/04 - FISICA NUCLEARE E SUBNUCLEARE

Abstract

International audience; The assessment of the neutrino absolute mass scale is still a crucial challenge in today particle physics and cosmology. Beta or electron capture spectrum end-point study is currently the only experimental method which can provide a model independent measurement of the absolute scale of neutrino mass. HOLMES is an experiment to directly measure the neutrino mass by performing a calorimetric measurement of the energy released in the electron capture decay of the artificial isotope 163Ho. In a calorimetric measurement the energy released in the decay process is entirely contained into the detector, except for the fraction taken away by the neutrino. This approach eliminates both the issues related to the use of an external source and the systematic uncertainties arising from decays on excited final states. HOLMES will deploy a large array of low temperature microcalorimeters implanted with 163Ho nuclei. The achievable neutrino mass statistical sensitivity is expected in the eV range, thereby making HOLMES an important step forward in the direct neutrino mass measurement with a calorimetric approach as an alternative to spectrometry. HOLMES will also establish the potential of this approach to achieve a sub-eV sensitivity. HOLMES is designed to collect about 3 × 1013 decays with an instrumental energy resolution around 1 eV FWHM and a time resolution around 1 µs. To achieve this in three years of measuring time, HOLMES is going to deploy 16 sub-arrays of TES microcalorimeters. Each sub-array has 64 pixels ion implanted with 163Ho nuclei to give a pixel activity of 300 Bq per pixel. The TES arrays are read out using microwave multiplexed rf-SQUIDs in combination with a Software Designed Radio data acquisition system. The commissioning of the first implanted sub-array is scheduled for 2018 and it will provide first high statistics data about the EC decay of 163Ho together with a preliminary limit on the neutrino mass. In this contribution we outline the HOLMES project with its physics reach and technical challenges, along with its status and perspectives. In particular we will present the status of the HOLMES activities concerning the 163Ho isotope production by neutron irradiation and purification, the TES pixel design and optimization, the multiplexed array read-out characterization, the cryogenic set-up installation, and the setting up of the mass separation and ion implantation system for the isotope embedding in the TES absorbers.

Published

2018

19. High energy resolution thermal microcalorimeters for the HOLMES experiment

Author

M. Faverzani, M. De Gerone, Flavio Gatti, A. Orlando, D. Bennet, Michele Biasotti, Dan Becker, Daniel Schmidt, Joseph W. Fowler, Evelyn Ferri, Carl D. Reintsema, John A. B. Mates, A. Nucciotti, Johnathon D. Gard, S. Ragazzi, Daniel S. Swetz, G. Gallucci, A. Puiu, James P. Hays-Wehle, Joel N. Ullom, Gene C. Hilton, V. Ceriale, Leila R. Vale, G. Pessina, Bradley K. Alpert, Andrea Giachero, Faverzani, M, Alpert, B, Becker, D, Bennet, D, Biasotti, M, Ceriale, V, De Gerone, M, Ferri, E, Fowler, J, Gallucci, G, Gard, J, Gatti, F, Giachero, A, Hays-Wehle, J, Hilton, G, Mates, J, Nucciotti, A, Orlando, A, Pessina, G, Puiu, A, Ragazzi, S, Reintsema, C, Schmidt, D, Swetz, D, Ullom, J, and Vale, L

Subjects

X-ray detector, Nuclear and High Energy Physics, Physics::Instrumentation and Detectors, Electron capture, Superconducting detector, 01 natural sciences, 7. Clean energy, Multiplexing, Optics, 0103 physical sciences, Thermal, 010306 general physics, Instrumentation, 010302 applied physics, Physics, business.industry, Transition edge sensors, Detector, Response time, X-ray detectors, Superconducting detectors, High Energy Physics::Experiment, Neutrino, business, Transition edge sensor, Microwave

Abstract

HOLMES is an experiment aimed at directly measuring the neutrino mass through the calorimetric measurement of the 163Ho electron capture decay. The final goal of the project consists in providing a sensitivity on the neutrino mass below 2 eV; in addition, it will establish the potential of this approach to achieve a sub-eV sensitivity. The detectors performances play a crucial role in achieving the desired sensitivity. Indeed, for such an experiment, the following characteristics are required: short response time ( ∼ 1 μ s ) to solve pile-up events, great energy resolution ( ∼ 1 eV @ 2.8 keV) and compatibility to be multiplexed in large detector arrays ( ≳ 1000). HOLMES will deploy 1000 Transition Edge Sensors which will be readout with the microwave multiplexing technique. In this contribution we outline the experimental setup used in the characterization phase of the detectors.

Published

2018

20. Updates on the Transition-Edge Sensors and Multiplexed Readout for HOLMES

Author

Dan Becker, V. Ceriale, Michele Biasotti, A. Nucciotti, Joseph W. Fowler, Daniel S. Swetz, A. Puiu, Emanuele Ferri, M. Faverzani, Andrea Giachero, A. Orlando, James P. Hays-Wehle, M. De Gerone, G. Gallucci, Leila R. Vale, Joel N. Ullom, M. Borghesi, G. Pessina, John A. B. Mates, Johnathon D. Gard, Daniel Schmidt, D. A. Bennett, Gene C. Hilton, Puiu, A, Becker, D, Bennett, D, Biasotti, M, Borghesi, M, Ceriale, V, de Gerone, M, Faverzani, M, Ferri, E, Fowler, J, Gallucci, G, Gard, J, Hays-Wehle, J, Hilton, G, Giachero, A, Mates, J, Nucciotti, A, Orlando, A, Pessina, G, Schmidt, D, Swetz, D, Ullom, J, and Vale, L

Subjects

Atomic and Molecular Physics, and Optic, Physics::Instrumentation and Detectors, Electron capture, 01 natural sciences, Multiplexing, HOLMES, 010305 fluids & plasmas, Optics, Multiplexed readout, Neutrino mass, rf-SQUID, Atomic and Molecular Physics, and Optics, Materials Science (all), Condensed Matter Physics, Atomic and Molecular Physics, 0103 physical sciences, General Materials Science, Dilution refrigerator, Sensitivity (control systems), 010306 general physics, Physics, business.industry, Detector, Order (ring theory), Calorimeter, High Energy Physics::Experiment, Neutrino, and Optics, business, Neutrino ma

Abstract

Measuring the neutrino mass is one of the most compelling issues in particle physics. HOLMES is an experiment for a direct measurement of the neutrino mass. HOLMES will perform a precise measurement of the end point of the electron capture decay spectrum of $$^{163}\hbox {Ho}$$ in order to extract information on the neutrino mass with a sensitivity as low as 1 eV. HOLMES, in its final configuration, will deploy a 1000-pixel array of low-temperature microcalorimeters: each calorimeter is made of an absorber, where the Ho atoms will be implanted, coupled to a transition-edge sensor (TES) thermometer. The detectors will be operated at the working temperature of $$100\,\hbox { mK}$$ provided by a dilution refrigerator. In order to read out the 1000-detector array of HOLMES, a multiplexing system is necessary: the choice is to couple the transition-edge sensors to a multiplexed rf-SQUID. In this contribution we outline the progress made towards the final configuration of HOLMES regarding both the performances of the TES detectors and the characteristics of the multiplexing system.

Published

2018

21. High energy resolution thermal microcalorimeters for the HOLMES experiment.

Author

Faverzani, M., Alpert, B., Becker, D., Bennet, D., Biasotti, M., Ceriale, V., De Gerone, M., Ferri, E., Fowler, J., Gallucci, G., Gard, J., Gatti, F., Giachero, A., Hays-Wehle, J., Hilton, G., Mates, J., Nucciotti, A., Orlando, A., Pessina, G., and Puiu, A.

Subjects

*HEAT, *ELECTRON capture, *NEUTRINOS, *CALORIMETERS, *NEUTRINO mass, *PHASE detectors

Abstract

HOLMES is an experiment aimed at directly measuring the neutrino mass through the calorimetric measurement of the 163Ho electron capture decay. The final goal of the project consists in providing a sensitivity on the neutrino mass below 2 eV; in addition, it will establish the potential of this approach to achieve a sub-eV sensitivity. The detectors performances play a crucial role in achieving the desired sensitivity. Indeed, for such an experiment, the following characteristics are required: short response time (∼ 1 μ s) to solve pile-up events, great energy resolution (∼ 1 eV @ 2.8 keV) and compatibility to be multiplexed in large detector arrays (≳ 1000). HOLMES will deploy 1000 Transition Edge Sensors which will be readout with the microwave multiplexing technique. In this contribution we outline the experimental setup used in the characterization phase of the detectors. • Transition Edge Sensors. • Neutrino mass measurement. • Multiplexed readout. [ABSTRACT FROM AUTHOR]

Published

2019

22. Status of the HOLMES detector development

Author

Michele Biasotti, C. Brofferio, Joseph W. Fowler, Gene C. Hilton, Rugard Dressler, U. Koester, M. De Gerone, G. Pizzigoni, Peter Day, Emanuele Ferri, R. Nizzolo, Daniel Schmidt, D. Corsini, L. Parodi, Elisa Fumagalli, M. Lusignoli, V. Ceriale, John A. B. Mates, Stefano Nisi, Monica Sisti, M. Ribeiro-Gomes, James P. Hays-Wehle, Carl D. Reintsema, A. Nucciotti, Daniel S. Swetz, M. Faverzani, Leila R. Vale, S. Ragazzi, G. Pessina, Joel N. Ullom, Angelo Orlando, F. Siccardi, D. A. Bennett, Johnathon D. Gard, Flavio Gatti, Dorothea Schumann, G. Ceruti, A. Puiu, Andrea Giachero, Daniel T. Becker, M. Maino, F. Terranova, S. Heinitz, Bradley K. Alpert, Nucciotti, A, Alpert, B, Becker, D, Bennett, D, Biasotti, M, Brofferio, C, Ceriale, V, Ceruti, G, Corsini, D, Day, P, De Gerone, M, Dressler, R, Faverzani, M, Ferri, E, Fowler, J, Fumagalli, E, Gard, J, Gatti, F, Giachero, A, Hays Wehle, J, Heinitz, S, Hilton, G, Koester, U, Lusignoli, M, Maino, M, Mates, J, Nisi, S, Nizzolo, R, Orlando, A, Parodi, L, Pessina, G, Pizzigoni, G, Puiu, P, Ragazzi, S, Reintsema, C, Ribeiro Gomes, M, Schmidt, D, Schumann, D, Siccardi, F, Sisti, M, Swetz, D, Terranova, F, Ullom, J, and Vale, L

Subjects

010302 applied physics, Physics, Nuclear and High Energy Physics, Electron capture, Instrumentation, Detector, Resolution (electron density), Ho-163, Low temperature detectors, Neutrino mass, 02 engineering and technology, 021001 nanoscience & nanotechnology, 01 natural sciences, Nuclear physics, Full width at half maximum, Low temperature detector, 0103 physical sciences, Neutrino, 0210 nano-technology, Neutrino ma, Sensitivity (electronics), Energy (signal processing)

Abstract

HOLMES is a new experiment to directly measure the neutrino mass with a sensitivity as low as 0.4 eV. HOLMES will perform a calorimetric measurement of the energy released in the electron capture decay of 163 Ho. HOLMES will deploy a large array of low temperature microcalorimeters with implanted 163 Ho nuclei. HOLMES baseline detector is an array of 1000 microcalorimeters each with an implanted 163 Ho activity of about 300 Bq, an energy resolution FWHM of about 1 eV at the spectrum end-point ( Q ≈ 2.5 keV), and a time resolution of about 1 μs. Matching these performances requires a careful optimization of all components, from the microcalorimeters to the signal processing algorithms. We outline here the project technical challenges and the present status of the development.

Published

2016

23. Status of the HOLMES detector development.

Author

Nucciotti, A., Alpert, B., Becker, D., Bennett, D., Biasotti, M., Brofferio, C., Ceriale, V., Ceruti, G., Corsini, D., Day, P., De Gerone, M., Dressler, R., Faverzani, M., Ferri, E., Fowler, J., Fumagalli, E., Gard, J., Gatti, F., Giachero, A., and Hays-Wehle, J.

Subjects

*NEUTRINO mass, *CALORIMETRY, *ELECTRON capture, *LOW temperatures, *OPTICAL resolution

Abstract

HOLMES is a new experiment to directly measure the neutrino mass with a sensitivity as low as 0.4 eV. HOLMES will perform a calorimetric measurement of the energy released in the electron capture decay of 163 Ho. HOLMES will deploy a large array of low temperature microcalorimeters with implanted 163 Ho nuclei. HOLMES baseline detector is an array of 1000 microcalorimeters each with an implanted 163 Ho activity of about 300 Bq, an energy resolution FWHM of about 1 eV at the spectrum end-point ( Q ≈ 2.5 keV), and a time resolution of about 1 μs. Matching these performances requires a careful optimization of all components, from the microcalorimeters to the signal processing algorithms. We outline here the project technical challenges and the present status of the development. [ABSTRACT FROM AUTHOR]

Published

2016

24. Status of the HOLMES experiment to directly measure the electron neutrino mass with a calorimetric approach

Author

Gallucci, G., Alpert, B., Balata, M., Becker, D. T., Bennett, D. A., Bevilacqua, A., Biasotti, M., Matteo Borghesi, Ceruti, G., Gerone, M., Dressler, R., Faverzani, M., Ferri, E., Fowler, J. W., Gard, J. D., Gatti, F., Giachero, A., Hays-Wehle, J. P., Heinitz, S., Hilton, G. C., Koster, U., Lusignoli, M., Mates, J. A. B., Nisi, S., Nucciotti, A., Parodi, L., Pessina, G., Puiu, A., Ragazzi, S., Reintsema, C. D., Schmidt, D. R., Schuman, D., Siccardit, F., Sisti, M., Swetz, D. S., Ullom, J. N., Vale, L. R., Gallucci, G, Alpert, B, Balata, M, Becker, D, Bennett, D, Bevilacqua, A, Biasotti, M, Borghesi, M, Ceruti, G, de Gerone, M, Dressler, R, Faverzani, M, Ferri, E, Fowler, J, Gard, J, Gatti, F, Giachero, A, Hays-Wehle, J, Heinitz, S, Hilton, G, Koster, U, Lusignoli, M, Mates, J, Nisi, S, Nucciotti, A, Parodi, L, Pessina, G, Puiu, A, Ragazzi, S, Reintsema, C, Schmidt, D, Schuman, D, Siccardit, F, Sisti, M, Swetz, D, Ullom, J, Vale, L, Institut Laue-Langevin (ILL), and ILL

Subjects

Electron capture, measurement methods, Measure (physics), chemistry.chemical_element, neutrino/e: mass, electron: capture, 01 natural sciences, neutrino mass, HOLMES, Nuclear physics, 0103 physical sciences, calorimeter, [PHYS.HEXP]Physics [physics]/High Energy Physics - Experiment [hep-ex], holmium: nuclide, [PHYS.PHYS.PHYS-INS-DET]Physics [physics]/Physics [physics]/Instrumentation and Detectors [physics.ins-det], 010306 general physics, activity report, detector: design, Physics, Calorimeter (particle physics), 010308 nuclear & particles physics, Detector, Neutrino physic, chemistry, pile-up, Transition edge sensor, Neutrino, Holmium, Electron neutrino

Abstract

International audience; The measurement of neutrino masses is still one of the most compelling issues in modern particle physics. HOLMES is an experiment that aims to measure the effective νe mass using a calorimetric approach. It will measure the spectrum end point of the electron capture (EC) decay of $^{163}$Ho. The very low Q-value (2.8 keV) of the decay and its half life (4570 y) are optimal to reach simultaneously a reasonable activity to have sufficient statistics in the end-point, reducing the pile-up probability and have a small quantity of $^{163}$Ho embedded in the detector not to alter significantly its heat capacity. Holmium will be implanted into a micro calorimeter made by a metallic absorber coupled to transition edge sensor (TES). Each detector will be implanted with around 300 Bq of holmium and the goal of the experiment is implanting ≈500 detectors (8x64 array of detectors) to reach an accuracy of the order of eV. In this contribution, we show the HOLMES experiment with its physics reach and technical challenges, along with its status and perspectives.