Your search keyword '"Kadribasic, F."' showing total 6 results

1. Electromagnetic modeling and science reach of DMRadio-m$^3$

Author

DMRadio Collaboration, AlShirawi, A., Bartram, C., Benabou, J. N., Brouwer, L., Chaudhuri, S., Cho, H. -M., Corbin, J., Craddock, W., Droster, A., Foster, J. W., Fry, J. T., Graham, P. W., Henning, R., Irwin, K. D., Kadribasic, F., Kahn, Y., Keller, A., Kolevatov, R., Kuenstner, S., Kurita, N., Leder, A. F., Li, D., Ouellet, J. L., Pappas, K. M. W., Phipps, A., Rapidis, N. M., Safdi, B. R., Salemi, C. P., Simanovskaia, M., Singh, J., van Assendelft, E. C., van Bibber, K., Wells, K., Winslow, L., Wisniewski, W. J., and Young, B. A.

Subjects

High Energy Physics - Experiment, Astrophysics - Cosmology and Nongalactic Astrophysics, High Energy Physics - Phenomenology, Physics - Instrumentation and Detectors

Abstract

DMRadio-m$^3$ is an experiment that is designed to be sensitive to KSVZ and DFSZ QCD axion models in the 10-200 MHz (41 neV$/c^2$ - 0.83 $\mu$eV/$c^2$) range. The experiment uses a solenoidal dc magnetic field to convert an axion dark-matter signal to an ac electromagnetic response in a coaxial copper pickup. The current induced by this axion signal is measured by dc SQUIDs. In this work, we present the electromagnetic modeling of the response of the experiment to an axion signal over the full frequency range of DMRadio-m$^3$, which extends from the low-frequency, lumped-element limit to a regime where the axion Compton wavelength is only a factor of two larger than the detector size. With these results, we determine the live time and sensitivity of the experiment. The primary science goal of sensitivity to DFSZ axions across 30-200 MHz can be achieved with a $3\sigma$ live scan time of 3.7 years., Comment: 14 pages, 6 figures

Published

2023

2. Projected Sensitivity of DMRadio-m$^3$: A Search for the QCD Axion Below $1\,\mu$eV

Author

DMRadio Collaboration, Brouwer, L., Chaudhuri, S., Cho, H. -M., Corbin, J., Craddock, W., Dawson, C. S., Droster, A., Foster, J. W., Fry, J. T., Graham, P. W., Henning, R., Irwin, K. D., Kadribasic, F., Kahn, Y., Keller, A., Kolevatov, R., Kuenstner, S., Leder, A. F., Li, D., Ouellet, J. L., Pappas, K., Phipps, A., Rapidis, N. M., Safdi, B. R., Salemi, C. P., Simanovskaia, M., Singh, J., van Assendelft, E. C., van Bibber, K., Wells, K., Winslow, L., Wisniewski, W. J., and Young, B. A.

Subjects

High Energy Physics - Experiment, High Energy Physics - Phenomenology, Physics - Instrumentation and Detectors

Abstract

The QCD axion is one of the most compelling candidates to explain the dark matter abundance of the universe. With its extremely small mass ($\ll 1\,\mathrm{eV}/c^2$), axion dark matter interacts as a classical field rather than a particle. Its coupling to photons leads to a modification of Maxwell's equations that can be measured with extremely sensitive readout circuits. DMRadio-m$^3$ is a next-generation search for axion dark matter below $1\,\mu$eV using a $>4$ T static magnetic field, a coaxial inductive pickup, a tunable LC resonator, and a DC-SQUID readout. It is designed to search for QCD axion dark matter over the range $20\,\mathrm{neV}\lesssim m_ac^2\lesssim 800\,\mathrm{neV}$ ($5\,\mathrm{MHz}<\nu<200\,\mathrm{MHz}$). The primary science goal aims to achieve DFSZ sensitivity above $m_ac^2\approx 120$ neV (30 MHz), with a secondary science goal of probing KSVZ axions down to $m_ac^2\approx40\,\mathrm{neV}$ (10 MHz)., Comment: 8 pages, 4 figures. Updated to fix small errors and correct acknowledgements. Updated title and notational clarifications

Published

2022

3. Introducing DMRadio-GUT, a search for GUT-scale QCD axions

Author

Brouwer, L., Chaudhuri, S., Cho, H. -M., Corbin, J., Dawson, C. S., Droster, A., Foster, J. W., Fry, J. T., Graham, P. W., Henning, R., Irwin, K. D., Kadribasic, F., Kahn, Y., Keller, A., Kolevatov, R., Kuenstner, S., Leder, A. F., Li, D., Ouellet, J. L., Pappas, K. M. W., Phipps, A., Rapidis, N. M., Safdi, B. R., Salemi, C. P., Simanovskaia, M., Singh, J., van Assendelft, E. C., van Bibber, K., Wells, K., Winslow, L., Wisniewski, W. J., and Young, B. A.

Subjects

High Energy Physics - Experiment, High Energy Physics - Phenomenology

Abstract

The QCD axion is a leading dark matter candidate that emerges as part of the solution to the strong CP problem in the Standard Model. The coupling of the axion to photons is the most common experimental probe, but much parameter space remains unexplored. The coupling of the QCD axion to the Standard Model scales linearly with the axion mass; therefore, the highly-motivated region 0.4-120 neV, corresponding to a GUT-scale axion, is particularly difficult to reach. This paper presents the design requirements for a definitive search for GUT-scale axions and reviews the technological advances needed to enable this program., Comment: 16 pages, 4 figures

Published

2022

4. Large-mass single-electron-resolution detector for dark matter and neutrino elastic interaction searches

Author

Iyer, V., Mirabolfathi, N., Agnolet, G., Chen, H., Jastram, A., Kadribasic, F., Kashyap, V. K. S., Kubik, A., Lee, M., Mahapatra, R., Mohanty, B., Neog, H., and Platt, M.

Subjects

Physics - Instrumentation and Detectors, High Energy Physics - Experiment

Abstract

Large mass single-electron-resolution solid state detectors are desirable to search for low mass dark matter candidates and to measure coherent elastic neutrino nucleus scattering (CE$\nu$NS). Here, we present results from a novel 100 g phonon-mediated Si detector with a new interface architecture. This detector gives a baseline resolution of $\sim 1 e^{-}/h^{+}$ pair and a leakage current on the order of $10^{-16}$ A. This was achieved by removing the direct electrical contact between the Si crystal and the metallic electrode, and by increasing the phonon absorption efficiency of the sensors. The phonon signal amplification in the detector shows a linear increase while the signal to noise ratio improves with bias voltage, up to 240 V. This feature enables the detector to operate at a low energy threshold which is beneficial for dark matter and CE$\nu$NS like searches., Comment: 6 pages, 5 figures

Published

2020

5. Background Studies for the MINER Coherent Neutrino Scattering Reactor Experiment

Author

MINER Collaboration, Agnolet, G., Baker, W., Barker, D., Beck, R., Carroll, T. J., Cesar, J., Cushman, P., Dent, J. B., De Rijck, S., Dutta, B., Flanagan, W., Fritts, M., Gao, Y., Harris, H. R., Hays, C. C., Iyer, V., Jastram, A., Kadribasic, F., Kennedy, A., Kubik, A., Ogawa, I., Lang, K., Mahapatra, R., Mandic, V., Martin, R. D., Mast, N., McDeavitt, S., Mirabolfathi, N., Mohanty, B., Nakajima, K., Newhouse, J., Newstead, J. L., Phan, D., Proga, M., Roberts, A., Rogachev, G., Salazar, R., Sander, J., Senapati, K., Shimada, M., Strigari, L., Tamagawa, Y., Teizer, W., Vermaak, J. I. C., Villano, A. N., Walker, J., Webb, B., Wetzel, Z., and Yadavalli, S. A.

Subjects

Physics - Instrumentation and Detectors, High Energy Physics - Experiment

Abstract

The proposed Mitchell Institute Neutrino Experiment at Reactor (MINER) experiment at the Nuclear Science Center at Texas A&M University will search for coherent elastic neutrino-nucleus scattering within close proximity (about 2 meters) of a 1 MW TRIGA nuclear reactor core using low threshold, cryogenic germanium and silicon detectors. Given the Standard Model cross section of the scattering process and the proposed experimental proximity to the reactor, as many as 5 to 20 events/kg/day are expected. We discuss the status of preliminary measurements to characterize the main backgrounds for the proposed experiment. Both in situ measurements at the experimental site and simulations using the MCNP and GEANT4 codes are described. A strategy for monitoring backgrounds during data taking is briefly discussed., Comment: 12 pages, 14 figures

Published

2016

6. Background Studies for the MINER Coherent Neutrino Scattering Reactor Experiment

Author

Miner, Collaboration, Agnolet, G., Baker, W., Barker, D., Beck, R., Carroll, T. J., Cesar, J., Cushman, P., Dent, J. B., Rijck, S., Dutta, B., Flanagan, W., Fritts, M., Gao, Y., Harris, H. R., Hays, C. C., Iyer, V., Jastram, A., Kadribasic, F., Kennedy, A., Kubik, A., Ogawa, I., Lang, K., Mahapatra, R., Mandic, V., Martin, R. D., Mast, N., Mcdeavitt, S., Mirabolfathi, N., Mohanty, B., Nakajima, K., Newhouse, J., Newstead, J. L., Phan, D., Proga, M., Roberts, A., Rogachev, G., Salazar, R., Sander, J., Senapati, K., Shimada, M., Louis Strigari, Tamagawa, Y., Teizer, W., Vermaak, J. I. C., Villano, A. N., Walker, J., Webb, B., Wetzel, Z., and Yadavalli, S. A.

Subjects

High Energy Physics - Experiment (hep-ex), Physics - Instrumentation and Detectors, FOS: Physical sciences, Instrumentation and Detectors (physics.ins-det), High Energy Physics - Experiment

Abstract

The proposed Mitchell Institute Neutrino Experiment at Reactor (MINER) experiment at the Nuclear Science Center at Texas A&M University will search for coherent elastic neutrino-nucleus scattering within close proximity (about 2 meters) of a 1 MW TRIGA nuclear reactor core using low threshold, cryogenic germanium and silicon detectors. Given the Standard Model cross section of the scattering process and the proposed experimental proximity to the reactor, as many as 5 to 20 events/kg/day are expected. We discuss the status of preliminary measurements to characterize the main backgrounds for the proposed experiment. Both in situ measurements at the experimental site and simulations using the MCNP and GEANT4 codes are described. A strategy for monitoring backgrounds during data taking is briefly discussed., 12 pages, 14 figures

Published

2016