Exploring freeze-out and freeze-in dark matter via effective Froggatt-Nielsen theory

被引：1

作者：

Mandal, Rusa ^{[1
]}

Tong, Tom ^{[2
]}

机构：

[1] Indian Inst Technol Gandhinagar, Dept Phys, Gandhinagar 382355, Gujarat, India

[2] Univ Siegen, Ctr Particle Phys Siegen CPPS, Theoret Phys 1, D-57068 Siegen, Germany

来源：

JOURNAL OF COSMOLOGY AND ASTROPARTICLE PHYSICS | 2023年 / 11期

关键词：

dark matter theory; particle physics-cosmology connection; neutrino theory; MASSES; PROGRAM; LIMITS;

D O I：

10.1088/1475-7516/2023/11/074

中图分类号：

P1 [天文学];

学科分类号：

0704 ;

摘要：

Motivated by the dynamical reasons for the hierarchical structure of the Yukawa sector of the Standard Model (SM), we consider an extension of the SM with a complex scalar field, known as 'flavon', based on the Froggatt-Nielsen mechanism. In an effective theory approach, the SM fermion masses and mixing patterns are generated in orders of the parameter related to the vacuum expectation value of the flavon field and the cut-off of the effective theory. By introducing right-handed neutrinos, we study the viability of the lightest right-handed neutrino as a dark matter candidate, where the same flavon field acts as a mediator between the dark and the SM sectors. We find that dark matter genesis is achieved both through freeze-out and freeze-in mechanisms encompassing the O(GeV) - O(TeV) mass range of the mediator and the dark matter particle. In addition to tree-level spin-dependent cross section, the model gives rise to tree-and loop-level contributions to spin-independent scattering cross section at the direct detection experiments such as XENON and LUX-ZEPLIN which can be probed in their future upgrades. By choosing suitable Froggatt-Nielsen charges for the fermions, we also generate the mass spectrum of the SM neutrinos via the Type-I seesaw mechanism. Flavor-changing neutral current processes, such as radiative lepton decay, meson mixing, and top-quark decay remain the most constraining channels and provide testability for this minimal setup that addresses several major shortcomings of the SM.

引用

页数：36

共 69 条

[1] DARWIN: towards the ultimate dark matter detector
Aalbers, J.
Agostini, F.
Alfonsi, M.
Amaro, F. D.
Amsler, C.
Aprile, E.
Arazi, L.
Arneodo, F.
Barrow, P.
Baudis, L.
Benabderrahmane, M. L.
Berger, T.
Beskers, B.
Breskin, A.
Breur, P. A.
Brown, A.
Brown, E.
Bruenner, S.
Bruno, G.
Budnik, R.
Butikofer, L.
Calven, J.
Cardoso, J. M. R.
Cichon, D.
Coderre, D.
Colijn, A. P.
Conrad, J.
Cussonneau, J. P.
Decowski, M. P.
Diglio, S.
Drexlin, G.
Duchovni, E.
Erdal, E.
Eurin, G.
Ferella, A.
Fieguth, A.
Fulgione, W.
Rosso, A. Gallo
Di Gangi, P.
Di Giovanni, A.
Galloway, M.
Garbini, M.
Geis, C.
Glueck, F.
Grandi, L.
Greene, Z.
Grignon, C.
Hasterok, C.
Hannen, V.
Hogenbirk, E.
[J]. JOURNAL OF COSMOLOGY AND ASTROPARTICLE PHYSICS, 2016, (11):
[2] First Dark Matter Search Results from the LUX-ZEPLIN (LZ) Experiment
Aalbers, J.
Akerib, D. S.
Akerlof, C. W.
Musalhi, A. K. Al
Alder, F.
Alqahtani, A.
Alsum, S. K.
Amarasinghe, C. S.
Ames, A.
Anderson, T. J.
Angelides, N.
Araujo, H. M.
Armstrong, J. E.
Arthurs, M.
Azadi, S.
Bailey, A. J.
Baker, A.
Balajthy, J.
Balashov, S.
Bang, J.
Bargemann, J. W.
Barry, M. J.
Barthel, J.
Bauer, D.
Baxter, A.
Beattie, K.
Belle, J.
Beltrame, P.
Bensinger, J.
Benson, T.
Bernard, E. P.
Bhatti, A.
Biekert, A.
Biesiadzinski, T. P.
Birch, H. J.
Birrittella, B.
Blockinger, G. M.
Boast, K. E.
Boxer, B.
Bramante, R.
Brew, C. A. J.
Bras, P.
Buckley, J. H.
V. Bugaev, V.
Burdin, S.
Busenitz, J. K.
Buuck, M.
Cabrita, R.
Carels, C.
Carlsmith, D. L.
[J]. PHYSICAL REVIEW LETTERS, 2023, 131 (04)
[3] Planck 2018 results: VIII. Gravitational lensing
Aghanim, N.
Akrami, Y.
Ashdown, M.
Aumont, J.
Baccigalupi, C.
Ballardini, M.
Banday, A. J.
Barreiro, R. B.
Bartolo, N.
Basak, S.
Benabed, K.
Bernard, J. -P.
Bersanelli, M.
Bielewicz, P.
Bock, J. J.
Bond, J. R.
Borrill, J.
Bouchet, F. R.
Boulanger, F.
Bucher, M.
Burigana, C.
Calabrese, E.
Cardoso, J. -F.
Carron, J.
Challinor, A.
Chiang, H. C.
Colombo, L. P. L.
Combet, C.
Crill, B. P.
Cuttaia, F.
de Bernardis, P.
de Zotti, G.
Delabrouille, J.
Di Valentino, E.
Diego, J. M.
Dore, O.
Douspis, M.
Ducout, A.
Dupac, X.
Efstathiou, G.
Elsner, F.
Ensslin, T. A.
Eriksen, H. K.
Fantaye, Y.
Fernandez-Cobos, R.
Finelli, F.
Forastieri, F.
Frailis, M.
Fraisse, A. A.
Franceschi, E.
[J]. ASTRONOMY & ASTROPHYSICS, 2020, 641 (641)
[4] Agrawal P, 2010, Arxiv, DOI arXiv:1003.1912
[5] Projected WIMP sensitivity of the LUX-ZEPLIN dark matter experiment
Akerib, D. S.
Akerlof, C. W.
Alsum, S. K.
Araujo, H. M.
Arthurs, M.
Bai, X.
Bailey, A. J.
Balajthy, J.
Balashov, S.
Bauer, D.
Belle, J.
Beltrame, P.
Benson, T.
Bernard, E. P.
Biesiadzinski, T. P.
Boast, K. E.
Boxer, B.
Bras, P.
Buckley, J. H.
Bugaev, V. V.
Burdin, S.
Busenitz, J. K.
Carels, C.
Carlsmith, D. L.
Carlson, B.
Carmona-Benitez, M. C.
Chan, C.
Cherwinka, J. J.
Cole, A.
Cottle, A.
Craddock, W. W.
Currie, A.
Cutter, J. E.
Dahl, C. E.
de Viveiros, L.
Dobi, A.
Dobson, J. E. Y.
Druszkiewicz, E.
Edberg, T. K.
Edwards, W. R.
Fan, A.
Fayer, S.
Fiorucci, S.
Fruth, T.
Gaitskell, R. J.
Genovesi, J.
Ghag, C.
Gilchriese, M. G. D.
van der Grinten, M. G. D.
Hall, C. R.
[J]. PHYSICAL REVIEW D, 2020, 101 (05)
[6] FEYNRULES 2.0-A complete toolbox for tree-level phenomenology
Alloul, Adam
Christensen, Neil D.
Degrande, Celine
Duhr, Claude
Fuks, Benjamin
[J]. COMPUTER PHYSICS COMMUNICATIONS, 2014, 185 (08) : 2250 - 2300
[7] MadDM v.3.0: A comprehensive tool for dark matter studies
Ambrogi, Federico
Arina, Chiara
Backovic, Mihailo
Heisig, Jan
Maltoni, Fabio
Mantani, Luca
Mattelaer, Olivier
Mohlabeng, Gopolang
[J]. PHYSICS OF THE DARK UNIVERSE, 2019, 24
[8] Dark matter search results from the complete exposure of the PICO-60 C3F8 bubble chamber
Amole, C.
Ardid, M.
Arnquist, I. J.
Asner, D. M.
Baxter, D.
Behnke, E.
Bressler, M.
Broerman, B.
Cao, G.
Chen, C. J.
Chowdhury, U.
Clark, K.
Collar, J., I
Cooper, P. S.
Coutu, C. B.
Cowles, C.
Crisler, M.
Crowder, G.
Cruz-Venegas, N. A.
Dahl, C. E.
Das, M.
Follows, S.
Farine, J.
Felis, I
Filgas, R.
Girard, F.
Giroux, G.
Hall, J.
Hardy, C.
Harris, O.
Hillier, T.
Hoppe, E. W.
Jackson, C. M.
Jin, M.
Klopfenstein, L.
Kozynets, T.
Krauss, C. B.
Laurin, M.
Lawson, I
Leblanc, A.
Levine, I
Licciardi, C.
Lippincott, W. H.
Loer, B.
Mamedov, F.
Mitra, P.
Moore, C.
Nania, T.
Neilson, R.
Noble, A. J.
[J]. PHYSICAL REVIEW D, 2019, 100 (02)
[9] First Dark Matter Search with Nuclear Recoils from the XENONnT Experiment
Aprile, E.
Abe, K.
Agostini, F.
Maouloud, S. Ahmed
Althueser, L.
Andrieu, B.
Angelino, E.
Angevaare, J. R.
Antochi, V. C.
Martin, D. Anton
Arneodo, F.
Baudis, L.
Baxter, A. L.
Bazyk, M.
Bellagamba, L.
Biondi, R.
Bismark, A.
Brookes, E. J.
Brown, A.
Bruenner, S.
Bruno, G.
Budnik, R.
Bui, T. K.
Cai, C.
Cardoso, J. M. R.
Cichon, D.
Chavez, A. P. Cimental
Colijn, A. P.
Conrad, J.
Cuenca-Garcia, J. J.
Cussonneau, J. P.
D'Andrea, V
Decowski, M. P.
Di Gangi, P.
Di Pede, S.
Diglio, S.
Eitel, K.
Elykov, A.
Farrell, S.
Ferella, A. D.
Ferrari, C.
Fischer, H.
Flierman, M.
Fulgione, W.
Fuselli, C.
Gaemers, P.
Gaior, R.
Rosso, A. Gallo
Galloway, M.
Gao, F.
[J]. PHYSICAL REVIEW LETTERS, 2023, 131 (04)
[10] Pseudoscalar mediators: a WIMP model at the neutrino floor
Arcadi, Giorgio
Linder, Manfred
Queiroz, Farinaldo S.
Rodejohann, Werner
Vogl, Stefan
[J]. JOURNAL OF COSMOLOGY AND ASTROPARTICLE PHYSICS, 2018, (03):

← 1 2 3 4 5 6 7 →