22,264 results
Search Results
2. Hot QCD White Paper
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Arslandok, M., Bass, S. A., Baty, A. A., Bautista, I., Beattie, C., Becattini, F., Bellwied, R., Berdnikov, Y., Berdnikov, A., Bielcik, J., Blair, J. T., Bock, F., Boimska, B., Bossi, H., Caines, H., Chen, Y., Chien, Y. -T., Chiu, M., Connors, M. E., Csanád, M., da Silva, C. L., Dash, A. P., David, G., Dehmelt, K., Dexheimer, V., Dong, X., Drees, A., Du, L., Durham, J. M., Ehlers, R. J., Elfner, H., Evdokimov, O., Finger, M., Finger Jr., M., Frantz, J., Frawley, A. D., Gale, C., Geurts, F., Gonzalez, V., Grau, N., Greene, S. V., Grossberndt, S. K., Hachiya, T., He, X., Heinz, U., Hong, B., Humanic, T. J., Ivanishchev, D., Jacak, B. V., Jahan, J., Jeon, S., Jheng, H. R., Jia, J., Judd, E. G., Kapusta, J. I., Karpenko, I., Khachatryan, V., Kharzeev, D. E., Kim, M., Kimelman, B., Klay, J. L., Klein, S. R., Knospe, A. G., Koch, V., Kotov, D, Krintiras, G. K., Elayavalli, R. Kunnawalkam, Kuo, C. M., Lajoie, J. G., Lee, Y. -J., Li, W., Liao, J., Likmeta, I., Lim, S. H., Liu, M. X., Loizides, C., Longo, R., Luo, X., Luzum, M., Ma, R., Majumder, A., Mak, S., Markert, C., Mehtar-Tani, Y., Mignerey, A. C., Minafra, N., Morrison, D. P., Mueller, B., Nagle, J. L., Narde, A., Nattrass, C. E., Niida, T., Noronha, J., Noronha-Hostler, J., Nouicer, R., Novitzky, N., O'Brien, E., Odyniec, G., Okorokov, V. A., Osborn, J. D., Paquet, J. -F., Park, S., Parotto, P., Perepelitsa, D. V., Petreczky, P., Pinkenburg, C., Praszalowicz, M., Pruneau, C., Putschke, J., Ramasubramanian, N. V., Rapp, R., Ratti, C., Read, K. F., Teles, P. Rebello, Reed, R., Rinn, T., Roland, G., Rosati, M., Royon, C., Ruan, L., Sakaguchi, T., Salur, S., Sarsour, M., Menon, A. S., Schenke, B., Schmidt, N. V., Schmier, A., Schäfer, T., Seger, J., Seto, R., Sheibani, Oveis, Shen, C., Shi, Z., Shulga, E., Sickles, A. M., Singh, M., Singh, B. K., Smirnov, N., Smith, K. L., Song, H., Soudi, I., Leiton, A. G. Stahl, Steinberg, P., Stephanov, M., Strickland, M., Sumbera, M., Cerci, D. Sunar, Tachibana, Y., Tang, A. H., Takaki, D. Tapia, Teaney, D., Thomas, D., Timmins, A. R., Tribedy, P., Tu, Z., Tuo, S., Rueda, O. V., Velkovska, J., Venugopalan, R., Videbæk, F., Voloshin, S. A., Vovchenko, V., Vujanovic, G., Wang, X., Wang, F., Wang, X. -N., Weyhmiller, S., Xie, W., Xu, N., Yang, Y., Yao, X., Ye, Z., Yee, H. -U., and Zajc, W. A.
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Nuclear Experiment ,High Energy Physics - Experiment ,High Energy Physics - Phenomenology ,Nuclear Theory - Abstract
Hot QCD physics studies the nuclear strong force under extreme temperature and densities. Experimentally these conditions are achieved via high-energy collisions of heavy ions at the Relativistic Heavy Ion Collider (RHIC) and the Large Hadron Collider (LHC). In the past decade, a unique and substantial suite of data was collected at RHIC and the LHC, probing hydrodynamics at the nucleon scale, the temperature dependence of the transport properties of quark-gluon plasma, the phase diagram of nuclear matter, the interaction of quarks and gluons at different scales and much more. This document, as part of the 2023 nuclear science long range planning process, was written to review the progress in hot QCD since the 2015 Long Range Plan for Nuclear Science, as well as highlight the realization of previous recommendations, and present opportunities for the next decade, building on the accomplishments and investments made in theoretical developments and the construction of new detectors. Furthermore, this document provides additional context to support the recommendations voted on at the Joint Hot and Cold QCD Town Hall Meeting, which are reported in a separate document., Comment: 190 pages, 69 figures
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- 2023
3. Single Vector-Like top quark production via chromomagnetic interactions at present and future hadron colliders $-$A Snowmass 2021 White Paper
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Belyaev, Alexander, Chivukula, R. Sekhar, Fuks, Benjamin, Simmons, Elizabeth H., and Wang, Xing
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High Energy Physics - Phenomenology ,High Energy Physics - Experiment - Abstract
In our recent paper, we have investigated the potential for the LHC to discover vector-like quark partner states singly produced via their chromomagnetic moment interactions. These production mechanisms extend traditional searches which rely on pair-production of top-quark partner states or on the single production of these states through electroweak interactions, in the sense of providing greatly increased reach in parameter space regions where traditional searches are insensitive. In this study we determine the potential of both the 14 TeV high-luminosity LHC (HL-LHC) and a 100 TeV proton-proton collider to probe new vector-like quarks produced in this mode. We focus on the single production of a top-quark partner in association with an ordinary top-quark, as well as on the resonant production of the bottom-quark partner with its subsequent decay to a top-quark partner and a $W$ boson. For both cases we consider a top-partner decay to the Higgs boson and an ordinary top-quark. We find that HL-LHC and a future 100 TeV proton collider can probe vector-like partner masses up to about 3 TeV and 15-20 TeV respectively, visibly extending the range of the traditional vector like quark partner searches., Comment: 14 pages, 5 figures. Contribution to Snowmass 2021. arXiv admin note: substantial text overlap with arXiv:2107.12402
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- 2022
4. Snowmass 2021 White Paper: Cosmogenic Dark Matter and Exotic Particle Searches in Neutrino Experiments
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Berger, J., Brailsford, D., Choi, K., Crespo-Anadón, J. I., Cui, Y., Das, A., Dror, J. A., Habig, A., Itow, Y., Kearns, E., Kim, D., Park, J. -C., Petrillo, G., Rott, C., Sen, M., Takhistov, V., Tsai, Y. -T., and Yu, J.
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High Energy Physics - Phenomenology ,High Energy Physics - Experiment - Abstract
The signals from outer space and their detection have been playing an important role in particle physics, especially in discoveries of and searches for physics beyond the Standard Model (BSM); beyond the evidence of dark matter (DM), for example, the neutrinos produced from the dark matter annihilation is important for the indirect DM searches. Moreover, a wide range of new, well-motivated physics models and dark-sector scenarios have been proposed in the last decade, predicting cosmogenic signals complementary to those in the conventional direct detection of particle-like dark matter. Most notably, various mechanisms to produce (semi-)relativistic DM particles in the present universe (e.g. boosted dark matter) have been put forward, while being consistent with current observational and experimental constraints on DM. The resulting signals often have less intense and more energetic fluxes, to which underground, kiloton-scale neutrino detectors can be readily sensitive. In addition, the scattering of slow-moving DM can give rise to a sizable energy deposit if the underlying dark-sector model allows for a large mass difference between the initial and final state particles, and the neutrino experiments with large volume detectors are well suited for exploring these opportunities. This White Paper is devoted to discussing the scientific importance of the cosmogenic dark matter and exotic particle searches, not only overviewing the recent efforts in both the theory and the experiment communities but also providing future perspectives and directions on this research branch. A landscape of technologies used in neutrino detectors and their complementarity is discussed, and the current and developing analysis strategies are outlined., Comment: Add a reference to the snowmass white paper
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- 2022
5. Snowmass White Paper: New flavors and rich structures in dark sectors
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Harris, Philip, Schuster, Philip, and Zupan, Jure
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High Energy Physics - Phenomenology ,High Energy Physics - Experiment - Abstract
Dark matter can be part of a dark sector with non-minimal couplings to the Standard Model. Compared to many (minimal) benchmark models, such scenarios can result in significant modifications in experimental signatures and strongly impact experimental search sensitivity. In this white paper, we review several non-minimal dark sector models, including phenomenological consequences: models explaining $(g-2)_\mu$, inelastic dark matter, strongly interacting massive particles as dark matter candidates, and axions with flavorful couplings. The present exclusions and projected experimental sensitivities on these example dark sector models illustrate the robustness of the growing dark sector experimental effort -- both the broadness and the precision of existing searches -- probing theoretically interesting parameter space. They also illustrate some of the unique complementarity of different experimental approaches., Comment: Contribution to Snowmass 2021
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- 2022
6. Snowmass2021 Cosmic Frontier: Cosmic Microwave Background Measurements White Paper
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Chang, Clarence L., Huffenberger, Kevin M., Benson, Bradford A., Bianchini, Federico, Chluba, Jens, Delabrouille, Jacques, Flauger, Raphael, Hanany, Shaul, Jones, William C., Kogut, Alan J., McMahon, Jeffrey J., Meyers, Joel, Sehgal, Neelima, Simon, Sara M., Umilta, Caterina, Abazajian, Kevork N., Ahmed, Zeeshan, Akrami, Yashar, Anderson, Adam J., Ansarinejad, Behzad, Austermann, Jason, Baccigalupi, Carlo, Barkats, Denis, Barron, Darcy, Barry, Peter S., Battaglia, Nicholas, Baxter, Eric, Beck, Dominic, Bender, Amy N., Bennett, Charles, Beringue, Benjamin, Bischoff, Colin, Bleem, Lindsey, Bock, James, Bolliet, Boris, Bond, J Richard, Borrill, Julian, Brinckmann, Thejs, Brown, Michael L., Calabrese, Erminia, Carlstrom, John, Challinor, Anthony, Chang, Chihway, Chinone, Yuji, Clark, Susan E., Coulton, William, Cukierman, Ari, Cyr-Racine, Francis-Yan, Duff, Shannon M., Dvorkin, Cora, van Engelen, Alexander, Errard, Josquin, Eskilt, Johannes R., Essinger-Hileman, Thomas, Fabbian, Giulio, Feng, Chang, Ferraro, Simone, Filippini, Jeffrey, Freese, Katherine, Galitzki, Nicholas, Gawiser, Eric, Grin, Daniel, Grohs, Evan, Gruppuso, Alessandro, Gudmundsson, Jon E., Halverson, Nils W., Hamilton, Jean-Christophe, Harrington, Kathleen, Henrot-Versillé, Sophie, Hensley, Brandon, Hill, J. Colin, Hincks, Adam D., Hlozek, Renee, Holzapfel, William, Hotinli, Selim C., Hui, Howard, Ibitoye, Ayodeji, Johnson, Matthew, Johnson, Bradley R., Kang, Jae Hwan, Karkare, Kirit S., Knox, Lloyd, Kovac, John, Lau, Kenny, Legrand, Louis, Loverde, Marilena, Lubin, Philip, Ma, Yin-Zhe, Mroczkowski, Tony, Mukherjee, Suvodip, Münchmeyer, Moritz, Nagai, Daisuke, Nagy, Johanna, Niemack, Michael, Novosad, Valentine, Omori, Yuuki, Orlando, Giorgio, Pan, Zhaodi, Perotto, Laurence, Petroff, Matthew A., Pogosian, Levon, Pryke, Clem, Rahlin, Alexandra, Raveri, Marco, Reichardt, Christian L., Remazeilles, Mathieu, Rephaeli, Yoel, Ruhl, John, Schaan, Emmanuel, Shandera, Sarah, Shimon, Meir, Soliman, Ahmed, Stark, Antony A., Starkman, Glenn D., Stompor, Radek, Thakur, Ritoban Basu, Trendafilova, Cynthia, Tristram, Matthieu, Trivedi, Pranjal, Tucker, Gregory, Di Valentino, Eleonora, Vieira, Joaquin, Vieregg, Abigail, Wang, Gensheng, Watson, Scott, Wenzl, Lukas, Wollack, Edward J., Wu, W. L. Kimmy, Xu, Zhilei, Zegeye, David, and Zhang, Cheng
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Astrophysics - Cosmology and Nongalactic Astrophysics ,Astrophysics - Instrumentation and Methods for Astrophysics ,General Relativity and Quantum Cosmology ,High Energy Physics - Experiment ,High Energy Physics - Phenomenology - Abstract
This is a solicited whitepaper for the Snowmass 2021 community planning exercise. The paper focuses on measurements and science with the Cosmic Microwave Background (CMB). The CMB is foundational to our understanding of modern physics and continues to be a powerful tool driving our understanding of cosmology and particle physics. In this paper, we outline the broad and unique impact of CMB science for the High Energy Cosmic Frontier in the upcoming decade. We also describe the progression of ground-based CMB experiments, which shows that the community is prepared to develop the key capabilities and facilities needed to achieve these transformative CMB measurements., Comment: contribution to Snowmass 2021
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- 2022
7. Snowmass2021 Cosmic Frontier White Paper: Dark Matter Physics from Halo Measurements
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Bechtol, Keith, Birrer, Simon, Cyr-Racine, Francis-Yan, Schutz, Katelin, Adhikari, Susmita, Amin, Mustafa, Banerjee, Arka, Bird, Simeon, Blinov, Nikita, Boddy, Kimberly K., Boehm, Celine, Bundy, Kevin, Buschmann, Malte, Chakrabarti, Sukanya, Curtin, David, Dai, Liang, Drlica-Wagner, Alex, Dvorkin, Cora, Erickcek, Adrienne L., Gilman, Daniel, Heeba, Saniya, Kim, Stacy, Iršič, Vid, Leauthaud, Alexie, Lovell, Mark, Lukić, Zarija, Mao, Yao-Yuan, Mau, Sidney, Mitridate, Andrea, Mocz, Philip, Muñoz, Julian B., Nadler, Ethan O., Peter, Annika H. G., Price-Whelan, Adrian, Robertson, Andrew, Sabti, Nashwan, Sehgal, Neelima, Shipp, Nora, Simon, Joshua D., Singh, Rajeev, Van Tilburg, Ken, Wechsler, Risa H., Widmark, Axel, and Yu, Hai-Bo
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High Energy Physics - Phenomenology ,Astrophysics - Cosmology and Nongalactic Astrophysics ,Astrophysics - Astrophysics of Galaxies - Abstract
The non-linear process of cosmic structure formation produces gravitationally bound overdensities of dark matter known as halos. The abundances, density profiles, ellipticities, and spins of these halos can be tied to the underlying fundamental particle physics that governs dark matter at microscopic scales. Thus, macroscopic measurements of dark matter halos offer a unique opportunity to determine the underlying properties of dark matter across the vast landscape of dark matter theories. This white paper summarizes the ongoing rapid development of theoretical and experimental methods, as well as new opportunities, to use dark matter halo measurements as a pillar of dark matter physics., Comment: White paper submitted to the Proceedings of the US Community Study on the Future of Particle Physics (Snowmass 2021). 88 pages, 9 figures. Comments welcome
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- 2022
8. Theories and Experiments for Testable Baryogenesis Mechanisms: A Snowmass White Paper
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Barrow, J. L., Broussard, Leah, Cline, James M., Dev, P. S. Bhupal, Drewes, Marco, Elor, Gilly, Gardner, Susan, Ghiglieri, Jacopo, Harz, Julia, Kamyshkov, Yuri, Klaric, Juraj, Koerner, Lisa W., Laurent, Benoit, McGehee, Robert, Postma, Marieke, Shakya, Bibhushan, Shrock, Robert, van de Vis, Jorinde, and White, Graham
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High Energy Physics - Phenomenology ,High Energy Physics - Experiment ,High Energy Physics - Theory - Abstract
The baryon asymmetry of the Universe is one of the central motivations to expect physics beyond the Standard Model. In this Snowmass white paper, we review the challenges and opportunities in testing some of the central paradigms that predict physics at scales low enough to expect new experimental data in the next decade. Focusing on theoretical ideas and some of their experimental implications, in particular, we discuss neutron-antineutron transformations, flavor observables, next generation colliders, future neutron facilities, gravitational waves, searches for permanent electric dipole moments, $0\nu \beta \beta $ decay and some future large underground experiments as methods to test post-sphaleron baryogenesis, electroweak baryogenesis, mesogenesis and low scale leptogenesis. Finally, we comment on the cases where high scale physics can be probed through some of these same mechanisms., Comment: White paper to be submitted to the Snowmass Process' Rare Processes and Precision Measurements Frontier, Baryon and Lepton Number Violation Topical Group (This v2 version corrects a missing author and an author's name which was misspelled. Apologies to these authors for this oversight on the part of the submitter!)
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- 2022
9. New Ideas in Baryogenesis: A Snowmass White Paper
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Elor, Gilly, Harz, Julia, Ipek, Seyda, Shakya, Bibhushan, Blinov, Nikita, Co, Raymond T., Cui, Yanou, Dasgupta, Arnab, Davoudiasl, Hooman, Elahi, Fatemeh, Fridell, Kåre, Ghalsasi, Akshay, Harigaya, Keisuke, Hati, Chandan, Huang, Peisi, Maleknejad, Azadeh, McGehee, Robert, Morrissey, David E., Schmitz, Kai, Shamma, Michael, Shuve, Brian, Tucker-Smith, David, van de Vis, Jorinde, and White, Graham
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High Energy Physics - Phenomenology ,Astrophysics - Cosmology and Nongalactic Astrophysics ,High Energy Physics - Experiment - Abstract
The Standard Model of Particle Physics cannot explain the observed baryon asymmetry of the Universe. This observation is a clear sign of new physics beyond the Standard Model. There have been many recent theoretical developments to address this question. Critically, many new physics models that generate the baryon asymmetry have a wide range of repercussions for many areas of theoretical and experimental particle physics. This white paper provides an overview of such recent theoretical developments with an emphasis on experimental testability., Comment: Contribution to Snowmass 2021. Solicited white paper from TF08. v2: includes additional contributions
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- 2022
10. Snowmass White Paper: Belle II physics reach and plans for the next decade and beyond
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Aggarwal, Latika, Banerjee, Swagato, Bansal, Sunil, Bernlochner, Florian, Bertemes, Michel, Bhardwaj, Vishal, Bondar, Alexander, Browder, Thomas E., Cao, Lu, Campajola, Marcello, Casarosa, Giulia, Cecchi, Claudia, Cheaib, Racha, De Pietro, Giacomo, Di Canto, Angelo, Dorigo, Mirco, Feichtinger, Paul, Ferber, Torben, Fulsom, Bryan, García, Marcela, Gaudino, Giovanni, Gaz, Alessandro, Glazov, Alexander, Granderath, Svenja, Graziani, Enrico, Greenwald, Daniel, Goldenzweig, Pablo, Heredia, Ivan, Villanueva, Michel Hernández, Higuchi, Takeo, Humair, Thibaud, Iijima, Toru, Inguglia, Gianluca, Ishikawa, Akimasa, Jacobi, Daniel, Junkerkalefeld, Henrik A., Karl, Robert, Lautenbach, Klemens, Lewis, Peter M., Li, Long-Ke, Lacaprara, Stefano, Libby, James, Manoni, Elisa, Martini, Alberto, Merola, Mario, Milesi, Marco, Moneta, Stefano, Nayak, Minakshi, Nishida, Shohei, Palaia, Maria Antonietta, Pham, Francis, Polat, Léonard, Prell, Soeren A., Prencipe, Elisabetta, Räuber, Géraldine, Ripp-Baudot, Isabelle, Rhorken, Markus, Roney, Michael, Rostomyan, Armine, Sakai, Yoshihide, Sato, Yo, Schwanda, Christoph, Schwartz, Alan J., Serrano, Justine, Sutcliffe, William, Svidras, Henrikas, Tackmann, Kerstin, Tamponi, Umberto, Tenchini, Francesco, Trabelsi, Karim, Tiwary, Rahul, Tonelli, Diego, Uno, Kenta, Vossen, Anselm, Yabsley, Bruce, Yin, Jun-Hao, and Zani, Laura
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High Energy Physics - Experiment ,High Energy Physics - Phenomenology - Abstract
Belle II is an experiment operating at the intensity frontier. Over the next decades, it will record the decay of billions of bottom mesons, charm hadrons, and tau leptons produced in 10 GeV electron-positron collisions at the SuperKEKB high-luminosity collider at KEK. These data, collected in low-background and kinematically known conditions, will allow us to measure hundreds of parameters that test the standard model (SM) and probe for the existence of new particles, at mass scales orders of magnitudes higher than those studied at the energy frontier. We project our sensitivities for measurements that are of primary relevance and where Belle II will be unique or world leading for data corresponding to 1 to 50 ab$^{-1}$. Belle II will uniquely probe non-SM contributions in sensitive $b \to q\bar q s$ decays and charmless $b \to q\bar q d(u)$ decays, semileptonic $b \to s \nu \bar\nu$ and $s \tau^+ \tau^-$ decays, fully leptonic $b \to \ell \nu$ decays, and select $c \to u$ processes. Belle II will lead exploration of non-SM physics in $b \to c \tau \nu$ and $b \to s \gamma$ decays and will most precisely determine the quark-mixing parameters $|V_{ub}|$ and $|V_{cb}|$. Belle II will measure many parameters in $\tau$ physics to precisions that will be world leading for the foreseeable future, including the electric and magnetic dipole moments, branching fractions for charged-lepton-flavor-violating decays, and quantities that test lepton-flavor universality. Belle II will perform unique searches for dark-sector particles with masses in the MeV-GeV range. We will also pursue a broad spectroscopy program for conventional and multiquark $c \bar c$ and $b \bar b$ states and provide essential inputs to sharpen the interpretation of muon magnetic-anomaly results. Our exploration of uncharted regions of non-SM parameter space with high precision will reveal non-SM particles or set stringent constraints on their existence, guiding future endeavors., Comment: 49 pages, 15 figures. Submitted to the Proceedings of the US Community Study on the Future of Particle Physics (Snowmass 2021)
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- 2022
11. A lattice QCD perspective on weak decays of b and c quarks Snowmass 2022 White Paper
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Boyle, Peter A., Chakraborty, Bipasha, Davies, Christine T. H., DeGrand, Thomas, DeTar, Carleton, Del Debbio, Luigi, El-Khadra, Aida X., Erben, Felix, Flynn, Jonathan M., Gámiz, Elvira, Giusti, Davide, Gottlieb, Steven, Hansen, Maxwell T., Heitger, Jochen, Hill, Ryan, Jay, William I., Jüttner, Andreas, Koponen, Jonna, Kronfeld, Andreas, Lehner, Christoph, Lytle, Andrew T., Martinelli, Guido, Meinel, Stefan, Monahan, Christopher J., Neil, Ethan T., Portelli, Antonin, Simone, James N., Simula, Silvano, Sommer, Rainer, Soni, Amarjit, Tsang, J. Tobias, Van de Water, Ruth S., Vaquero, Alejandro, Vittorio, Ludovico, and Witzel, Oliver
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High Energy Physics - Lattice ,High Energy Physics - Experiment ,High Energy Physics - Phenomenology - Abstract
Lattice quantum chromodynamics has proven to be an indispensable method to determine nonperturbative strong contributions to weak decay processes. In this white paper for the Snowmass community planning process we highlight achievements and future avenues of research for lattice calculations of weak $b$ and $c$ quark decays, and point out how these calculations will help to address the anomalies currently in the spotlight of the particle physics community. With future increases in computational resources and algorithmic improvements, percent level (and below) lattice determinations will play a central role in constraining the standard model or identifying new physics., Comment: contribution to Snowmass 2021; 19 pages; v2 corrected typo and added references
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- 2022
12. Snowmass White Paper: Prospects of CP-violation measurements with the Higgs boson at future experiments
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Gritsan, A. V., Bahl, H., Barman, R. K., Bozovic-Jelisavcic, I., Davis, J., Dekens, W., Gao, Y., Goncalves, D., Guerra, L. S. Mandacaru, Jeans, D., Kong, K., Kyriacou, S., Mohan, K., Pan, R. -Q., Roskes, J., Tran, N. V., Vukasinovic, N., and Xiao, M.
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High Energy Physics - Experiment ,High Energy Physics - Phenomenology - Abstract
The search for CP violation in interactions of the Higgs boson with either fermions or bosons provides attractive reference measurements in the Particle Physics Community Planning Exercise (a.k.a. "Snowmass"). Benchmark measurements of CP violation provide a limited and well-defined set of parameters that could be tested at the proton, electron-positron, photon, and muon colliders, and compared to those achieved through study of virtual effects in electric dipole moment measurements. We review the current status of these CP-sensitive studies and provide projections to future measurements., Comment: Snowmass White Paper. 25 pages, 6 figures
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- 2022
13. Snowmass White Paper: the Double Copy and its Applications
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Adamo, Tim, Carrasco, John Joseph M., Carrillo-González, Mariana, Chiodaroli, Marco, Elvang, Henriette, Johansson, Henrik, O'Connell, Donal, Roiban, Radu, and Schlotterer, Oliver
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High Energy Physics - Theory ,General Relativity and Quantum Cosmology ,High Energy Physics - Phenomenology ,Mathematical Physics - Abstract
The double copy is, in essence, a map between scattering amplitudes in a broad variety of familiar field and string theories. In addition to the mathematically rich intrinsic structure, it underlies a multitude of active research directions and has a range of interesting applications in quantum, classical and effective field theories, including broad topics such as string theory, particle physics, astrophysics, and cosmology. This Snowmass white paper provides a brief introduction to the double copy, its applications, current research and future challenges., Comment: 53 pages + refs, 4 figures, contribution to Snowmass 2021; feedback welcome, contact: JJ Carrasco
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- 2022
14. Snowmass2021 - White Paper, Implications of Energy Peak for Collider Phenomenology: Top Quark Mass Determination and Beyond
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Agashe, Kaustubh, Airen, Sagar, Franceschini, Roberto, Kim, Doojin, and Sathyan, Deepak
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High Energy Physics - Phenomenology ,High Energy Physics - Experiment - Abstract
We first review the decade-old, broad collider physics research program dubbed energy-peaks. We consider the energy distribution of a massless particle in the lab frame arising from the two-body decay of a heavy particle produced unpolarized, whose boost distribution is arbitrary. Remarkably, the location of the peak of this child particle's energy distribution is identical to its single-valued energy in the rest frame of the parent, which is a function of the parent's mass and that of the other decay product. We summarize generalizations to other types of decay and a variety of applications to BSM. The energy-peak idea can also furnish a measurement of the top quark via the energy of the bottom quark from its decay, which, based on the "parent-boost-invariance," is less sensitive to details of the production mechanism of the top quark (cf.~most other methods assume purely SM production of the top quarks, hence are subject to uncertainties therein, including a possible BSM contribution). The original proposal along this line was to simply use the $b$-jet energy as a very good approximation to the bottom quark energy. This method has been successfully implemented by the CMS collaboration. However, the $b$-jet energy-peak method is afflicted by the jet-energy scale (JES) uncertainty. Fortunately, this drawback can be circumvented by using the decay length of a $B$-hadron contained in the $b$-jet as a proxy for the bottom quark energy. An interesting proposal is to then appropriately dovetail the above two ideas resulting in a "best of both worlds" determination of the top quark mass, i.e., based on a measurement of the $B$-hadron decay length, but improved by the energy-peak concept: this would be free of JES uncertainty and largely independent of the top quark production model. We summarize here the results of such an analysis which is to appear in a forthcoming paper., Comment: Contribution to Snowmass 2021
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- 2022
15. Snowmass White Paper: prospects for measurements of the bottom quark mass
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Aparisi, Javier, Fuster, Juan, Hoang, Andre, Irles, Adrian, Lepenik, Christopher, Mateu, Vicent, Rodrigo, German, Spira, Michael, Tairafune, Seidai, Tian, Junping, Vos, Marcel, Yamamoto, Hitoshi, and Yonamine, Ryo
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High Energy Physics - Experiment ,High Energy Physics - Phenomenology - Abstract
In this white paper for the Snowmass '21 community planning exercise we provide quantitative prospects for bottom quark mass measurements in high-energy collisions at future colliders that can provide a precise test of the scale evolution, or "running" of quark masses predicted by QCD.
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- 2022
16. Snowmass2021 White Paper: Collider Physics Opportunities of Extended Warped Extra-Dimensional Models
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Agashe, Kaustubh, Collins, Jack H., Du, Peizhi, Ekhterachian, Majid, Hong, Sungwoo, Kim, Doojin, Mishra, Rashmish K., and Sathyan, Deepak
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High Energy Physics - Phenomenology - Abstract
While the warped extra-dimensional models provide an attractive solution to both the gauge and the flavor hierarchy problems, the mass scale of new particles predicted by the minimal models would be beyond the reach of the LHC. Models of extended warped extra dimensions have been proposed to evade these issues and their collider implications have been investigated for the last decade. This white paper summarizes the recent developments in the context of collider phenomenology. The strategies and lessons are broad, and provide a template to extend the experimental program, to cover a wider class of signals in other new physics scenarios as well., Comment: Contribution to Snowmass 2021
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- 2022
17. Neutrino Scattering Measurements on Hydrogen and Deuterium: A Snowmass White Paper
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Alvarez-Ruso, Luis, Barrow, Joshua L., Bellantoni, Leo, Betancourt, Minerba, Bross, Alan, Cremonesi, Linda, Duffy, Kirsty, Dytman, Steven, Fields, Laura, Fukuda, Tsutomu, González-Díaz, Diego, Gorchtein, Mikhail, Hill, Richard J., Junk, Thomas, Keller, Dustin, Lin, Huey-Wen, Lu, Xianguo, Mahn, Kendall, Meyer, Aaron S., Mohayai, Tanaz, Morfín, Jorge G., Owens, Joseph, Paley, Jonathan, Pandey, Vishvas, Paz, Gil, Petti, Roberto, Plestid, Ryan, Ramson, Bryan, Russell, Brooke, Nieto, Federico Sanchez, Tomalak, Oleksandr, Wilkinson, Callum, and Wret, Clarence
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High Energy Physics - Experiment ,High Energy Physics - Phenomenology - Abstract
Neutrino interaction uncertainties are a limiting factor in current and next-generation experiments probing the fundamental physics of neutrinos, a unique window on physics beyond the Standard Model. Neutrino-nucleon scattering amplitudes are an important part of the neutrino interaction program. However, since all modern neutrino detectors are composed primarily of heavy nuclei, knowledge of elementary neutrino-nucleon amplitudes relies heavily on experiments performed in the 1970s and 1980s, whose statistical and systematic precision are insufficient for current needs. In this white paper, we outline the motivation for attempting measurements on hydrogen and deuterium that would improve this knowledge, and we discuss options for making these measurements either with the DUNE near detector or with a dedicated facility., Comment: 66 pages, 10 figures. Submitted to the Proceedings of the US Community Study on the Future of Particle Physics (Snowmass 2021). v2: update author list and added citations
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- 2022
18. Snowmass2021 Cosmic Frontier CF6 White Paper: Multi-Experiment Probes for Dark Energy -- Transients
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Kim, Alex G., Palmese, Antonella, Pereira, Maria E. S., Aldering, Greg, Andrade-Oliveira, Felipe, Annis, James, Bailey, Stephen, BenZvi, Segev, Braga-Neto, Ulysses, Courbin, Frédéric, Garcia, Alyssa, Jeffery, David, Narayan, Gautham, Perlmutter, Saul, Soares-Santos, Marcelle, Treu, Tommaso, and Wang, Lifan
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Astrophysics - Cosmology and Nongalactic Astrophysics ,Astrophysics - Instrumentation and Methods for Astrophysics ,High Energy Physics - Experiment ,High Energy Physics - Phenomenology - Abstract
This invited Snowmass 2021 White Paper highlights the power of joint-analysis of astronomical transients in advancing HEP Science and presents research activities that can realize the opportunities that come with current and upcoming projects. Transients of interest include gravitational wave events, neutrino events, strongly-lensed quasars and supernovae, and Type~Ia supernovae specifically. These transients can serve as probes of cosmological distances in the Universe and as cosmic laboratories of extreme strong-gravity, high-energy physics. Joint analysis refers to work that requires significant coordination from multiple experiments or facilities so encompasses Multi-Messenger Astronomy and optical transient discovery and distributed follow-up programs., Comment: Minor updates to align with the feedback from the Snowmass Community Summer Study Workshop
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- 2022
19. Snowmass White Paper: Beyond the Standard Model effects on Neutrino Flavor
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Argüelles, C. A., Barenboim, G., Bustamante, M., Coloma, P., Denton, P. B., Esteban, I., Farzan, Y., Martínez, E. Fernández, Forero, D. V., Gago, A. M., Katori, T., Lehnert, R., Ross-Lonergan, M., Suliga, A. M., Tabrizi, Z., Anchordoqui, L., Chakraborty, K., Conrad, J., Das, A., Fong, C. S., Littlejohn, B. R., Maltoni, M., Parno, D., Spitz, J., Tang, J., and Wissel, S.
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High Energy Physics - Phenomenology ,High Energy Physics - Experiment - Abstract
Neutrinos are one of the most promising messengers for signals of new physics Beyond the Standard Model (BSM). On the theoretical side, their elusive nature, combined with their unknown mass mechanism, seems to indicate that the neutrino sector is indeed opening a window to new physics. On the experimental side, several long-standing anomalies have been reported in the past decades, providing a strong motivation to thoroughly test the standard three-neutrino oscillation paradigm. In this Snowmass21 white paper, we explore the potential of current and future neutrino experiments to explore BSM effects on neutrino flavor during the next decade., Comment: 54 pages plus references. Contact authors: P. Coloma, D. V. Forero and T. Katori. Comments welcome. Contribution to Snowmass 2021. v2 incorporates community feedback
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- 2022
- Full Text
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20. Scalar-mediated dark matter model at colliders and gravitational wave detectors -- A White paper for Snowmass 2021
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Liu, Jia, Wang, Xiao-Ping, and Xie, Ke-Pan
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High Energy Physics - Phenomenology ,Astrophysics - Cosmology and Nongalactic Astrophysics ,High Energy Physics - Experiment - Abstract
The weakly interacting massive particles (WIMPs) have been the most popular particle dark matter (DM) candidate for the last several decades, and it is well known that WIMP can be probed via the direct, indirect and collider experiments. However, the direct and indirect signals are highly suppressed in some scalar-mediated DM models, e.g. the lepton portal model with a Majorana DM candidate. As a result, collider searches are considered as the only hope to probe such models. In this white paper, we propose that the gravitational wave (GW) astronomy also serves as a powerful tool to probe such scalar mediated WIMP models via the potential first-order phase transition GW signals. An example for the lepton portal dark matter is provided, showing the complementarity between collider and GW probes., Comment: 4 pages + references, 2 figures, contribution to Snowmass 2021
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- 2022
21. Snowmass White Paper: Precision Studies of Spacetime Symmetries and Gravitational Physics
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Adelberger, Eric, Budker, Dmitry, Folman, Ron, Geraci, Andrew A., Harke, Jason T., Kaplan, Daniel M., Kimball, Derek F. Jackson, Lehnert, Ralf, Moore, David, Morley, Gavin W., Palladino, Anthony, Phillips, Thomas J., Piacentino, Giovanni M., Snow, William Michael, and Sudhir, Vivishek
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High Energy Physics - Experiment ,General Relativity and Quantum Cosmology ,High Energy Physics - Phenomenology ,High Energy Physics - Theory - Abstract
High-energy physics is primarily concerned with uncovering the laws and principles that govern nature at the fundamental level. Research in this field usually relies on probing the boundaries of established physics, an undertaking typically associated with extreme energy and distance scales. It is therefore unsurprising that particle physics has traditionally been dominated by large-scale experimental methods often involving high energies, such as colliders and storage rings, cosmological and astrophysical observations, large-volume detector systems, etc. However, high-sensitivity measurements in smaller experiments, often performed at lower energies, are presently experiencing a surge in importance for particle physics for at least two reasons. First, they exploit synergies to adjacent areas of physics with recent advances in experimental techniques and technology. Together with intensified phenomenological explorations, these advances have led to the realization that challenges associated with weak couplings or the expected suppression factors for new physics can be overcome with such methods while maintaining a large degree of experimental control. Second, many of these measurements broaden the range of particle-physics phenomena and observables relative to the above set of more conventional methodologies. Combining such measurements with the conventional efforts above therefore casts both a wider and tighter net for possible effects originating from physics beyond the Standard Model (BSM). This paper argues that this assessment points at a growing impact of such methods and measurements on high-energy physics, and therefore warrants direct support as particle-physics research. Leveraging the recent rapid progress and bright outlook associated with such studies for high-energy physics, could yield high returns, but requires substantial and sustained efforts by funding agencies., Comment: Contribution to Snowmass 2021, 55 pages, 5 figures
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- 2022
22. Snowmass 2021 White Paper: Higgs Coupling Sensitivities and Model-Independent Bounds on the Scale of New Physics
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Abu-Ajamieh, Fayez, Chang, Spencer, Chen, Miranda, Liu, Da, and Luty, Markus A.
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High Energy Physics - Phenomenology ,High Energy Physics - Experiment - Abstract
In this Snowmass white paper, we describe how unitarity bounds can convert sensitivities for Higgs couplings at future colliders into sensitivities to the scale of new physics. This gives a model-independent consequence of improving these sensitivities and illustrate the impact they would have on constraining new physics. Drawing upon past successful applications of unitarity as a guide for future colliders (e.g. the Higgs mass bound and discovering it at the LHC), we hope this data will be useful in the planning for next generation colliders., Comment: v2, 5 pages, added Muon Collider numbers, 2 added plots, contribution to Snowmass 2021
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- 2022
23. Snowmass2021 Cosmic Frontier White Paper:Primordial Black Hole Dark Matter
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Bird, Simeon, Albert, Andrea, Dawson, Will, Ali-Haimoud, Yacine, Coogan, Adam, Drlica-Wagner, Alex, Feng, Qi, Inman, Derek, Inomata, Keisuke, Kovetz, Ely, Kusenko, Alexander, Lehmann, Benjamin V., Munoz, Julian B., Singh, Rajeev, Takhistov, Volodymyr, and Tsai, Yu-Dai
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High Energy Physics - Phenomenology ,Astrophysics - Cosmology and Nongalactic Astrophysics - Abstract
Primordial Black Holes (PBHs) are a viable candidate to comprise some or all of the dark matter and provide a unique window into the high-energy physics of the early universe. This white paper discusses the scientific motivation, current status, and future reach of observational searches for PBHs. Future observational facilities supported by DOE, NSF, and NASA will provide unprecedented sensitivity to PBHs. However, devoted analysis pipelines and theoretical modeling are required to fully leverage these novel data. The search for PBHs constitutes a low-cost, high-reward science case with significant impact on the high energy physics community., Comment: 22 pages, 4 figures, submission to the Snowmass 2021 process. Update to add references
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- 2022
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24. Searches for Baryon Number Violation in Neutrino Experiments: A White Paper
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Dev, P. S. B., Koerner, L. W., Saad, S., Antusch, S., Askins, M., Babu, K. S., Barrow, J. L., Chakrabortty, J., de Gouvêa, A., Djurcic, Z., Girmohanta, S., Gogoladze, I., Goodman, M. C., Higuera, A., Kalra, D., Karagiorgi, G., Kearns, E., Kudryavtsev, V. A., Kutter, T., Ochoa-Ricoux, J. P., Malinský, M., Caicedo, D. A. Martinez, Mohapatra, R. N., Nath, P., Nussinov, S., Pec, V., Rafique, A., Rondon, J. Rodriguez, Shrock, R., Sobel, H. W., Stokes, T., Strait, M., Svoboda, R., Syritsyn, S., Takhistov, V., Tsai, Y. -T., Wendell, R. A., and Zhou, Y. -L.
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High Energy Physics - Experiment ,High Energy Physics - Phenomenology - Abstract
Baryon number conservation is not guaranteed by any fundamental symmetry within the Standard Model, and therefore has been a subject of experimental and theoretical scrutiny for decades. So far, no evidence for baryon number violation has been observed. Large underground detectors have long been used for both neutrino detection and searches for baryon number violating processes. The next generation of large neutrino detectors will seek to improve upon the limits set by past and current experiments and will cover a range of lifetimes predicted by several Grand Unified Theories. In this White Paper, we summarize theoretical motivations and experimental aspects of searches for baryon number violation in neutrino experiments., Comment: 73 pages, 19 figures
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- 2022
25. Snowmass 2021 White Paper: Resummation for future colliders
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van Beekveld, Melissa, Jaskiewicz, Sebastian, Liu, Tao, Liu, Xiaohui, Neill, Duff, Penin, Alexander, Ringer, Felix, Szafron, Robert, Vernazza, Leonardo, Vita, Gherardo, and Wang, Jian
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High Energy Physics - Phenomenology - Abstract
Resummation techniques are essential for high-precision phenomenology at current and future high-energy collider experiments. Perturbative computations of cross sections often suffer from large logarithmic corrections, which must be resummed to all orders to restore the reliability of predictions from first principles. The precise understanding of the all-order structure of field theories allows for fundamental tests of the Standard Model and new physics searches. In this white paper, we review recent progress in modern resummation techniques and outline future directions. In particular, we focus on the resummation beyond leading power, the joint resummation of different classes of logarithms relevant for jets and their substructure, small-$x$ resummation in the high-energy regime and the QCD fragmentation process in the small-$z_h$ limit., Comment: Contribution to Snowmass 2021
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- 2022
26. Snowmass2021 Cosmic Frontier White Paper: 21cm Radiation as a Probe of Physics Across Cosmic Ages
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Liu, Adrian, Newburgh, Laura, Saliwanchik, Benjamin, and Slosar, Anže
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Astrophysics - Cosmology and Nongalactic Astrophysics ,Astrophysics - Instrumentation and Methods for Astrophysics ,High Energy Physics - Experiment ,High Energy Physics - Phenomenology - Abstract
The 21cm line refers to a forbidden transition in neutral hydrogen associated with alignment of spins of the proton and electron. It is a very low energy transition that is emitted whenever there is neutral hydrogen in the Universe. Since baryons are mostly (~75%) hydrogen, one can in principle detect this emission throughout much of the history of the Universe. The dominant emission mechanism is different across cosmic ages. Before the photons decouple from matter, hydrogen is in an ionized state and does not emit in 21cm. After recombination and during the Dark Ages, at z ~ 30-1000, the 21cm emission is associated with density fluctuations in the neutral hydrogen medium. After the first stars turn on and galaxies begin to form, the 21cm emission traces bubbles of ionized hydrogen in the sea of the neutral medium. This epoch, spanning z ~ 6-30, is often referred to as cosmic dawn and the Epoch of Reionization (EoR). At redshifts below z<6, the intergalactic medium is largely ionized, but pockets of self-shielded neutral gas form in dense galactic environments and 21cm emission traces the distribution of galaxies. The vastly different emission mechanisms allow us to probe very different physics at different redshifts, corresponding to different observational frequencies. The instrumental challenges, namely building very sensitive and exquisitely calibrated radio telescopes, however, share many commonalities across frequency bands. The potential of the 21cm probe has been recognized by the Decadal Survey of Astronomy & Astrophysics, whose Panel on Cosmology identified the Dark Ages as its sole discovery area. We argue that HEP should recognize the potential of 21cm as a probe of fundamental physics across many axes and invest in the technology development that will enable full exploitation of this rich technique., Comment: Snowmass 2021 Solicited White Paper by the Cosmic Frontier 5 Topical Group
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- 2022
27. Snowmass White Paper: Flavor Model Building
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Altmannshofer, Wolfgang and Zupan, Jure
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High Energy Physics - Phenomenology - Abstract
In this white paper for the Snowmass process, we summarize the role flavor model building plays in the quest for new physics. We review approaches to address the non-generic flavor structure of the Standard Model and discuss how new physics models can be made compatible with the stringent constraints from flavor changing processes that indirectly probe very high scales. We also give an overview of the persistent anomalies in B decays and the anomalous magnetic moment of the muon and some of their most popular new physics explanations., Comment: 34 pages, 2 figures; contribution to Snowmass 2021; solicited whitepaper for TF08; comments are welcome; v2: references added; v3: more references added; v4: figure 1 corrected, more references added; v5: typos corrected
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- 2022
28. Snowmass White Paper: Effective Field Theories for Dark Matter Phenomenology
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Baumgart, Matthew, Bishara, Fady, Brod, Joachim, Cohen, Timothy, Fitzpatrick, A. Liam, Gorbahn, Martin, Moldanazarova, Ulserik, Reece, Matthew, Rodd, Nicholas L., Solon, Mikhail P., Szafron, Robert, Zhang, Zhengkang, and Zupan, Jure
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High Energy Physics - Phenomenology ,Astrophysics - Cosmology and Nongalactic Astrophysics ,Astrophysics - High Energy Astrophysical Phenomena - Abstract
The quest to discover the nature of dark matter continues to drive many of the experimental and observational frontiers in particle physics, astronomy, and cosmology. While there are no definitive signatures to date, there exists a rich ecosystem of experiments searching for signals for a broad class of dark matter models, at different epochs of cosmic history, and through a variety of processes with different characteristic energy scales. Given the multitude of candidates and search strategies, effective field theory has been an important tool for parametrizing the possible interactions between dark matter and Standard Model probes, for quantifying and improving model-independent uncertainties, and for robust estimation of detection rates in the presence of large perturbative corrections. This white paper summarizes a wide range of effective field theory applications for connecting dark matter theories to experiments., Comment: 30 pages, 8 figures
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- 2022
29. Snowmass White Paper: The Cosmological Bootstrap
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Baumann, Daniel, Green, Daniel, Joyce, Austin, Pajer, Enrico, Pimentel, Guilherme L., Sleight, Charlotte, and Taronna, Massimo
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High Energy Physics - Theory ,Astrophysics - Cosmology and Nongalactic Astrophysics ,General Relativity and Quantum Cosmology ,High Energy Physics - Phenomenology - Abstract
This white paper summarizes recent progress in the cosmological bootstrap, an approach to the study of the statistics of primordial fluctuations from consistency with unitarity, locality and symmetry assumptions. We review the key ideas of the bootstrap method, with an eye towards future directions and ambitions of the program. Focusing on recent progress involving de Sitter and quasi-de Sitter backgrounds, we highlight the role of singularities and unitarity in constraining the form of the correlators. We also discuss nonperturbative formulations of the bootstrap, connections to anti-de Sitter space, and potential implications for holography., Comment: 52 pages, 7 figures; Contribution to Snowmass 2021
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- 2022
30. Higgs Self Couplings Measurements at Future proton-proton Colliders: a Snowmass White Paper
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Taliercio, Angela, Mastrapasqua, Paola, Caputo, Claudio, Vischia, Pietro, De Filippis, Nicola, and Bhat, Pushpalatha
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High Energy Physics - Experiment ,High Energy Physics - Phenomenology - Abstract
The Higgs boson trilinear and quartic self-couplings are directly related to the shape of the Higgs potential; measuring them with precision is extremely important, as they provide invaluable information on the electroweak symmetry breaking and the electroweak phase transition. In this paper, we perform a detailed analysis of double Higgs boson production, through the gluon gluon fusion process, in the most promising decay channels di-bottom-quark di-photons, di-bottom-quark di-tau, and four-bottom-quark for several future colliders: the HL-LHC at 14 TeV and the FCC-hh at 100 TeV, assuming respectively 3 inverse ab and 30 inverse ab of integrated luminosity. In the HL LHC scenario, we expect an upper limit on the di Higgs cross section production of 0.76 at 95% confidence level, corresponding to a significance of 2.8 sigma. In the FCC-hh scenario, depending on the assumed detector performance and systematic uncertainties, we expect that the Higgs self-coupling will be measured with a precision in the range 4.8-8.5% at 95% confidence level., Comment: contribution to Snowmass 2021
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- 2022
31. Snowmass 2021 CMB-S4 White Paper
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Abazajian, Kevork, Abdulghafour, Arwa, Addison, Graeme E., Adshead, Peter, Ahmed, Zeeshan, Ajello, Marco, Akerib, Daniel, Allen, Steven W., Alonso, David, Alvarez, Marcelo, Amin, Mustafa A., Amiri, Mandana, Anderson, Adam, Ansarinejad, Behzad, Archipley, Melanie, Arnold, Kam S., Ashby, Matt, Aung, Han, Baccigalupi, Carlo, Baker, Carina, Bakshi, Abhishek, Bard, Debbie, Barkats, Denis, Barron, Darcy, Barry, Peter S., Bartlett, James G., Barton, Paul, Thakur, Ritoban Basu, Battaglia, Nicholas, Beall, Jim, Bean, Rachel, Beck, Dominic, Belkner, Sebastian, Benabed, Karim, Bender, Amy N., Benson, Bradford A., Besuner, Bobby, Bethermin, Matthieu, Bhimani, Sanah, Bianchini, Federico, Biquard, Simon, Birdwell, Ian, Bischoff, Colin A., Bleem, Lindsey, Bocaz, Paulina, Bock, James J., Bocquet, Sebastian, Boddy, Kimberly K., Bond, J. Richard, Borrill, Julian, Bouchet, Francois R., Brinckmann, Thejs, Brown, Michael L., Bryan, Sean, Buza, Victor, Byrum, Karen, Calabrese, Erminia, Calafut, Victoria, Caldwell, Robert, Carlstrom, John E., Carron, Julien, Cecil, Thomas, Challinor, Anthony, Chan, Victor, Chang, Clarence L., Chapman, Scott, Charles, Eric, Chauvin, Eric, Cheng, Cheng, Chesmore, Grace, Cheung, Kolen, Chinone, Yuji, Chluba, Jens, Cho, Hsiao-Mei Sherry, Choi, Steve, Clancy, Justin, Clark, Susan, Cooray, Asantha, Coppi, Gabriele, Corlett, John, Coulton, Will, Crawford, Thomas M., Crites, Abigail, Cukierman, Ari, Cyr-Racine, Francis-Yan, Dai, Wei-Ming, Daley, Cail, Dart, Eli, Daues, Gregorg, de Haan, Tijmen, Deaconu, Cosmin, Delabrouille, Jacques, Derylo, Greg, Devlin, Mark, Di Valentino, Eleonora, Dierickx, Marion, Dober, Brad, Doriese, Randy, Duff, Shannon, Dutcher, Daniel, Dvorkin, Cora, Dünner, Rolando, Eftekhari, Tarraneh, Eimer, Joseph, Bouhargani, Hamza El, Elleflot, Tucker, Emerson, Nick, Errard, Josquin, Essinger-Hileman, Thomas, Fabbian, Giulio, Fanfani, Valentina, Fasano, Alessandro, Feng, Chang, Ferraro, Simone, Filippini, Jeffrey P., Flauger, Raphael, Flaugher, Brenna, Fraisse, Aurelien A., Frisch, Josef, Frolov, Andrei, Galitzki, Nicholas, Gallardo, Patricio A., Galli, Silvia, Ganga, Ken, Gerbino, Martina, Giannakopoulos, Christos, Gilchriese, Murdock, Gluscevic, Vera, Goeckner-Wald, Neil, Goldfinger, David, Green, Daniel, Grimes, Paul, Grin, Daniel, Grohs, Evan, Gualtieri, Riccardo, Guarino, Vic, Gudmundsson, Jon E., Gullett, Ian, Guns, Sam, Habib, Salman, Haller, Gunther, Halpern, Mark, Halverson, Nils W., Hanany, Shaul, Hand, Emma, Harrington, Kathleen, Hasegawa, Masaya, Hasselfield, Matthew, Hazumi, Masashi, Heitmann, Katrin, Henderson, Shawn, Hensley, Brandon, Herbst, Ryan, Hervias-Caimapo, Carlos, Hill, J. Colin, Hills, Richard, Hivon, Eric, Hlozek, Renée, Ho, Anna, Holder, Gil, Hollister, Matt, Holzapfel, William, Hood, John, Hotinli, Selim, Hryciuk, Alec, Hubmayr, Johannes, Huffenberger, Kevin M., Hui, Howard, nez, Roberto Ibá, Ibitoye, Ayodeji, Ikape, Margaret, Irwin, Kent, Jacobus, Cooper, Jeong, Oliver, Johnson, Bradley R., Johnstone, Doug, Jones, William C., Joseph, John, Jost, Baptiste, Kang, Jae Hwan, Kaplan, Ari, Karkare, Kirit S., Katayama, Nobuhiko, Keskitalo, Reijo, King, Cesiley, Kisner, Theodore, Klein, Matthias, Knox, Lloyd, Koopman, Brian J., Kosowsky, Arthur, Kovac, John, Kovetz, Ely D., Krolewski, Alex, Kubik, Donna, Kuhlmann, Steve, Kuo, Chao-Lin, Kusaka, Akito, Lähteenmäki, Anne, Lau, Kenny, Lawrence, Charles R., Lee, Adrian T., Legrand, Louis, Leitner, Matthaeus, Leloup, Clément, Lewis, Antony, Li, Dale, Linder, Eric, Liodakis, Ioannis, Liu, Jia, Long, Kevin, Louis, Thibaut, Loverde, Marilena, Lowry, Lindsay, Lu, Chunyu, Lubin, Phil, Ma, Yin-Zhe, Maccarone, Thomas, Madhavacheril, Mathew S., Maldonado, Felipe, Mantz, Adam, Marques, Gabriela, Matsuda, Frederick, Mauskopf, Philip, May, Jared, McCarrick, Heather, McCracken, Ken, McMahon, Jeffrey, Meerburg, P. Daniel, Melin, Jean-Baptiste, Menanteau, Felipe, Meyers, Joel, Millea, Marius, Miranda, Vivian, Mitchell, Don, Mohr, Joseph, Moncelsi, Lorenzo, Monzani, Maria Elena, Moshed, Magdy, Mroczkowski, Tony, Mukherjee, Suvodip, Münchmeyer, Moritz, Nagai, Daisuke, Nagarajappa, Chandan, Nagy, Johanna, Namikawa, Toshiya, Nati, Federico, Natoli, Tyler, Nerval, Simran, Newburgh, Laura, Nguyen, Hogan, Nichols, Erik, Nicola, Andrina, Niemack, Michael D., Nord, Brian, Norton, Tim, Novosad, Valentine, O'Brient, Roger, Omori, Yuuki, Orlando, Giorgio, Osherson, Benjamin, Osten, Rachel, Padin, Stephen, Paine, Scott, Partridge, Bruce, Patil, Sanjaykumar, Petravick, Don, Petroff, Matthew, Pierpaoli, Elena, Pilleux, Mauricio, Pogosian, Levon, Prabhu, Karthik, Pryke, Clement, Puglisi, Giuseppe, Racine, Benjamin, Raghunathan, Srinivasan, Rahlin, Alexandra, Raveri, Marco, Reese, Ben, Reichardt, Christian L., Remazeilles, Mathieu, Rizzieri, Arianna, Rocha, Graca, Roe, Natalie A., Rotermund, Kaja, Roy, Anirban, Ruhl, John E., Saba, Joe, Sailer, Noah, Salatino, Maria, Saliwanchik, Benjamin, Sapozhnikov, Leonid, Rao, Mayuri Sathyanarayana, Saunders, Lauren, Schaan, Emmanuel, Schillaci, Alessandro, Schmitt, Benjamin, Scott, Douglas, Sehgal, Neelima, Shandera, Sarah, Sherwin, Blake D., Shirokoff, Erik, Shiu, Corwin, Simon, Sara M., Singari, Baibhav, Slosar, Anze, Spergel, David, Germaine, Tyler St., Staggs, Suzanne T., Stark, Antony A., Starkman, Glenn D., Steinbach, Bryan, Stompor, Radek, Stoughton, Chris, Suzuki, Aritoki, Tajima, Osamu, Tandoi, Chris, Teply, Grant P., Thayer, Gregg, Thompson, Keith, Thorne, Ben, Timbie, Peter, Tomasi, Maurizio, Trendafilova, Cynthia, Tristram, Matthieu, Tucker, Carole, Tucker, Gregory, Umiltà, Caterina, van Engelen, Alexander, van Marrewijk, Joshiwa, Vavagiakis, Eve M., Vergès, Clara, Vieira, Joaquin D., Vieregg, Abigail G., Wagoner, Kasey, Wallisch, Benjamin, Wang, Gensheng, Wang, Guo-Jian, Watson, Scott, Watts, Duncan, Weaver, Chris, Wenzl, Lukas, Westbrook, Ben, White, Martin, Whitehorn, Nathan, Wiedlea, Andrew, Williams, Paul, Wilson, Robert, Winch, Harrison, Wollack, Edward J., Wu, W. L. Kimmy, Xu, Zhilei, Yefremenko, Volodymyr G., Yu, Cyndia, Zegeye, David, Zivick, Jeff, and Zonca, Andrea
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Astrophysics - Cosmology and Nongalactic Astrophysics ,Astrophysics - Instrumentation and Methods for Astrophysics ,General Relativity and Quantum Cosmology ,High Energy Physics - Experiment ,High Energy Physics - Phenomenology - Abstract
This Snowmass 2021 White Paper describes the Cosmic Microwave Background Stage 4 project CMB-S4, which is designed to cross critical thresholds in our understanding of the origin and evolution of the Universe, from the highest energies at the dawn of time through the growth of structure to the present day. We provide an overview of the science case, the technical design, and project plan., Comment: Contribution to Snowmass 2021. arXiv admin note: substantial text overlap with arXiv:1908.01062, arXiv:1907.04473
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- 2022
32. Snowmass2021 Cosmic Frontier White Paper: Puzzling Excesses in Dark Matter Searches and How to Resolve Them
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Leane, Rebecca K., Shin, Seodong, Yang, Liang, Adhikari, Govinda, Alhazmi, Haider, Aramaki, Tsuguo, Baxter, Daniel, Calore, Francesca, Caputo, Regina, Cholis, Ilias, Daylan, Tansu, Di Mauro, Mattia, von Doetinchem, Philip, Han, Ke, Hooper, Dan, Horiuchi, Shunsaku, Kim, Doojin, Kong, Kyoungchul, Lang, Rafael F., Lin, Qing, Linden, Tim, Liu, Jianglai, Macias, Oscar, Mishra-Sharma, Siddharth, Murphy, Alexander, Rajaee, Meshkat, Rodd, Nicholas L., Parikh, Aditya, Park, Jong-Chul, Sarsa, Maria Luisa, Shockley, Evan, Slatyer, Tracy R., Takhistov, Volodymyr, Wagner, Felix, Ye, Jingqiang, Zaharijas, Gabrijela, Zhong, Yi-Ming, Zhou, Ning, and Zhou, Xiaopeng
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High Energy Physics - Phenomenology ,Astrophysics - High Energy Astrophysical Phenomena ,High Energy Physics - Experiment - Abstract
Intriguing signals with excesses over expected backgrounds have been observed in many astrophysical and terrestrial settings, which could potentially have a dark matter origin. Astrophysical excesses include the Galactic Center GeV gamma-ray excess detected by the Fermi Gamma-Ray Space Telescope, the AMS antiproton and positron excesses, and the 511 and 3.5 keV X-ray lines. Direct detection excesses include the DAMA/LIBRA annual modulation signal, the XENON1T excess, and low-threshold excesses in solid state detectors. We discuss avenues to resolve these excesses, with actions the field can take over the next several years., Comment: 57 pages, solicited white paper submitted to the Proceedings of the US Community Study on the Future of Particle Physics (Snowmass 2021)
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- 2022
33. Snowmass2021 Cosmic Frontier White Paper: Cosmology and Fundamental Physics from the three-dimensional Large Scale Structure
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Ferraro, Simone, Sailer, Noah, Slosar, Anze, and White, Martin
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Astrophysics - Cosmology and Nongalactic Astrophysics ,High Energy Physics - Experiment ,High Energy Physics - Phenomenology - Abstract
Advances in experimental techniques make it possible to map the high redshift Universe in three dimensions at high fidelity in the near future. This will increase the observed volume by many-fold, while providing unprecedented access to very large scales, which hold key information about primordial physics. Recently developed theoretical techniques, together with the smaller size of non-linearities at high redshift, allow the reconstruction of an order of magnitude more "primordial modes", and should improve our understanding of the early Universe through measurements of primordial non-Gaussianity and features in the primordial power spectrum. In addition to probing the first epoch of accelerated expansion, such measurements can probe the Dark Energy density in the dark matter domination era, tightly constraining broad classes of dynamical Dark Energy models. The shape of the matter power spectrum itself has the potential to detect sub-percent fractional amounts of Early Dark Energy to $z \sim 10^5$, probing Dark Energy all the way to when the Universe was only a few years old. The precision of these measurements, combined with CMB observations, also has the promise of greatly improving our constraints on the effective number of relativistic species, the masses of neutrinos, the amount of spatial curvature and the gravitational slip. Studies of linear or quasi-linear large-scale structure with redshift surveys and the CMB currently provide our tightest constraints on cosmology and fundamental physics. Pushing the redshift and volume frontier will provide guaranteed, significant improvements in the state-of-the-art in a manner that is easy to forecast and optimize., Comment: 26 pages, 8 figures; Snowmass2021 Cosmic Frontier White Paper
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- 2022
34. Snowmass White Paper: Probing New Physics with $\mu^+ \mu^- \to bs$ at a Muon Collider
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Altmannshofer, Wolfgang, Gadam, Sri Aditya, and Profumo, Stefano
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High Energy Physics - Phenomenology - Abstract
In this white paper for the Snowmass process, we discuss the prospects of probing new physics explanations of the persistent rare $B$ decay anomalies with a muon collider. If the anomalies are indirect signs of heavy new physics, non-standard rates for $\mu^+ \mu^- \to b s$ production should be observed with high significance at a muon collider with center of mass energy of $\sqrt{s} = 10$ TeV. The forward-backward asymmetry of the $b$-jet provides diagnostics of the chirality structure of the new physics couplings. In the absence of a signal, $\mu^+ \mu^- \to b s$ can indirectly probe new physics scales as large as $86$ TeV. Beam polarization would have an important impact on the new physics sensitivity., Comment: Contribution to Snowmass 2021
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- 2022
35. Snowmass2021 Cosmic Frontier White Paper: Prospects for obtaining Dark Matter Constraints with DESI
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Valluri, Monica, Chabanier, Solene, Irsic, Vid, Armengaud, Eric, Walther, Michael, Rockosi, Connie, Sanchez-Conde, Miguel A., Silva, Leandro Beraldo e, Cooper, Andrew P., Darragh-Ford, Elise, Dawson, Kyle, Deason, Alis J., Ferraro, Simone, Forero-Romero, Jaime E., Garzilli, Antonella, Li, Ting, Lukic, Zarija, Manser, Christopher J., Palanque-Delabrouille, Nathalie, Ravoux, Corentin, Tan, Ting, Wang, Wenting, Wechsler, Risa, Carrillo, Andreia, Dey, Arjun, Koposov, Sergey E., Mao, Yao-Yuan, Montero-Camacho, Paulo, Patel, Ekta, Rossi, Graziano, Urena-Lopez, L. Arturo, and Valenzuela, Octavio
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Astrophysics - Cosmology and Nongalactic Astrophysics ,Astrophysics - Astrophysics of Galaxies ,High Energy Physics - Phenomenology - Abstract
Despite efforts over several decades, direct-detection experiments have not yet led to the discovery of the dark matter (DM) particle. This has led to increasing interest in alternatives to the Lambda CDM (LCDM) paradigm and alternative DM scenarios (including fuzzy DM, warm DM, self-interacting DM, etc.). In many of these scenarios, DM particles cannot be detected directly and constraints on their properties can ONLY be arrived at using astrophysical observations. The Dark Energy Spectroscopic Instrument (DESI) is currently one of the most powerful instruments for wide-field surveys. The synergy of DESI with ESA's Gaia satellite and future observing facilities will yield datasets of unprecedented size and coverage that will enable constraints on DM over a wide range of physical and mass scales and across redshifts. DESI will obtain spectra of the Lyman-alpha forest out to z~5 by detecting about 1 million QSO spectra that will put constraints on clustering of the low-density intergalactic gas and DM halos at high redshift. DESI will obtain radial velocities of 10 million stars in the Milky Way (MW) and Local Group satellites enabling us to constrain their global DM distributions, as well as the DM distribution on smaller scales. The paradigm of cosmological structure formation has been extensively tested with simulations. However, the majority of simulations to date have focused on collisionless CDM. Simulations with alternatives to CDM have recently been gaining ground but are still in their infancy. While there are numerous publicly available large-box and zoom-in simulations in the LCDM framework, there are no comparable publicly available WDM, SIDM, FDM simulations. DOE support for a public simulation suite will enable a more cohesive community effort to compare observations from DESI (and other surveys) with numerical predictions and will greatly impact DM science., Comment: Contributed white paper to Snowmass 2021, CF03; minor revisions
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- 2022
36. Snowmass White Paper: Light Dark Matter Direct Detection at the Interface With Condensed Matter Physics
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Mitridate, Andrea, Trickle, Tanner, Zhang, Zhengkang, and Zurek, Kathryn M.
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High Energy Physics - Phenomenology ,Astrophysics - Cosmology and Nongalactic Astrophysics ,Condensed Matter - Materials Science - Abstract
Direct detection experiments for light (sub-GeV) dark matter are making enormous leaps in reaching previously unexplored theory space. The need for accurate characterizations of target responses has led to a growing interplay between particle and condensed matter physics. This white paper summarizes recent progress on direct detection calculations that utilize state-of-the-art numerical tools in condensed matter physics and effective field theory techniques. These new results provide the theoretical framework for interpreting ongoing and planned experiments using electronic and collective excitations, and for optimizing future searches., Comment: contribution to Snowmass 2021; 11 pages, 3 figures
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- 2022
37. Snowmass White Paper: Effective Field Theory Matching and Applications
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Cohen, Timothy, Lu, Xiaochuan, and Zhang, Zhengkang
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High Energy Physics - Phenomenology - Abstract
Mapping UV theories onto low energy effective descriptions is a procedure known as matching. The last decade has seen tremendous progress in the development of new tools for efficiently performing matching calculations, by relying on so-called functional methods. This white paper summarizes the status of functional matching. Specifically, matching for relativistic theories is a fully solved problem up to one-loop order in perturbation theory, and to arbitrary order in the effective field theory expansion. A streamlined prescription that has been partially automated facilitates the application of functional matching to phenomenological studies in the Standard Model EFT framework., Comment: contribution to Snowmass 2021; 10 pages
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- 2022
38. White Paper on Light Sterile Neutrino Searches and Related Phenomenology
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Acero, M. A., Argüelles, C. A., Hostert, M., Kalra, D., Karagiorgi, G., Kelly, K. J., Littlejohn, B., Machado, P., Pettus, W., Toups, M., Ross-Lonergan, M., Sousa, A., Surukuchi, P. T., Wong, Y. Y. Y., Abdallah, W., Abdullahi, A. M., Akutsu, R., Alvarez-Ruso, L., Alves, D. S. M., Aurisano, A., Balantekin, A. B., Berryman, J. M., Bertólez-Martínez, T., Brunner, J., Blennow, M., Bolognesi, S., Borusinski, M., Cianci, D., Collin, G., Conrad, J. M., Crow, B., Denton, P. B., Duvall, M., Fernández-Martinez, E., Fong, C. S., Foppiani, N., Forero, D. V., Friend, M., García-Soto, A., Giganti, C., Giunti, C., Gandhi, R., Ghosh, M., Hardin, J., Heeger, K. M., Ishitsuka, M., Izmaylov, A., Jones, B. J. P., Jordan, J. R., Kamp, N. W., Katori, T., Kim, S. B., Koerner, L. W., Lamoureux, M., Lasserre, T., Leach, K. G., Learned, J., Li, Y. F., Link, J. M., Louis, W. C., Mahn, K., Meyers, P. D., Maricic, J., Marko, D., Maruyama, T., Mertens, S., Minakata, H., Mocioiu, I., Mooney, M., Moulai, M. H., Nunokawa, H., Ochoa-Ricoux, J. P., Oh, Y. M., Ohlsson, T., Päs, H., Pershey, D., Robertson, R. G. H., Rosauro-Alcaraz, S., Rott, C., Roy, S., Salvado, J., Scott, M., Seo, S. H., Shaevitz, M. H., Smiley, M., Spitz, J., Stachurska, J., Thakore, T., Ternes, C. A., Thompson, A., Tseng, S., Vogelaar, B., Weiss, T., Wendell, R. A., Wright, T., Xin, Z., Yang, B. S., Yoo, J., Zennamo, J., Zettlemoyer, J., Zornoza, J. D., Ahmad, S., Basto-Gonzalez, V. S., Bowden, N. S., Cañas, B. C., Caratelli, D., Chang, C. V., Chen, C., Classen, T., Convery, M., Davies, G. S., Dennis, S. R., Djurcic, Z., Dorrill, R., Du, Y., Evans, J. J., Fahrendholz, U., Formaggio, J. A., Foust, B. T., Gatti, H. Frandini, Garcia-Gamez, D., Gariazzo, S., Gehrlein, J., Grant, C., Gomes, R. A., Hansell, A. B., Halzen, F., Ho, S., Zink, J. Hoefken, Jones, R. S., Kunkle, P., Li, J. -Y., Li, S. C., Luo, X., Malyshkin, Yu., Massaro, D., Mastbaum, A., Mohanta, R., Mumm, H. P., Nebot-Guinot, M., Neilson, R., Ni, K., Nieves, J., Gann, G. D. Orebi, Pandey, V., Pascoli, S., Qian, X., Rajaoalisoa, M., Roca, C., Roskovec, B., Saul-Sala, E., Saldaña, L., Scholberg, K., Shakya, B., Slocum, P. L., Snider, E. L., Steiger, H. Th. J., Steklain, A. F., Stock, M. R., Sutanto, F., Takhistov, V., Tsai, Y. -D., Tsai, Y. -T., Venegas-Vargas, D., Wallbank, M., Wang, E., Weatherly, P., Westerdale, S., Worcester, E., Wu, W., Yang, G., and Zamorano, B.
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High Energy Physics - Experiment ,Astrophysics - Cosmology and Nongalactic Astrophysics ,High Energy Physics - Phenomenology ,Physics - Instrumentation and Detectors - Abstract
This white paper provides a comprehensive review of our present understanding of experimental neutrino anomalies that remain unresolved, charting the progress achieved over the last decade at the experimental and phenomenological level, and sets the stage for future programmatic prospects in addressing those anomalies. It is purposed to serve as a guiding and motivational "encyclopedic" reference, with emphasis on needs and options for future exploration that may lead to the ultimate resolution of the anomalies. We see the main experimental, analysis, and theory-driven thrusts that will be essential to achieving this goal being: 1) Cover all anomaly sectors -- given the unresolved nature of all four canonical anomalies, it is imperative to support all pillars of a diverse experimental portfolio, source, reactor, decay-at-rest, decay-in-flight, and other methods/sources, to provide complementary probes of and increased precision for new physics explanations; 2) Pursue diverse signatures -- it is imperative that experiments make design and analysis choices that maximize sensitivity to as broad an array of these potential new physics signatures as possible; 3) Deepen theoretical engagement -- priority in the theory community should be placed on development of standard and beyond standard models relevant to all four short-baseline anomalies and the development of tools for efficient tests of these models with existing and future experimental datasets; 4) Openly share data -- Fluid communication between the experimental and theory communities will be required, which implies that both experimental data releases and theoretical calculations should be publicly available; and 5) Apply robust analysis techniques -- Appropriate statistical treatment is crucial to assess the compatibility of data sets within the context of any given model., Comment: Contribution to Snowmass 2021 by the NF02 Topical Group (Understanding Experimental Neutrino Anomalies). Submitted to J. Phys. G as a Major Report
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- 2022
39. Snowmass 2021 White Paper: The Windchime Project
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The Windchime Collaboration, Attanasio, Alaina, Bhave, Sunil A., Blanco, Carlos, Carney, Daniel, Demarteau, Marcel, Elshimy, Bahaa, Febbraro, Michael, Feldman, Matthew A., Ghosh, Sohitri, Hickin, Abby, Hong, Seongjin, Lang, Rafael F., Lawrie, Benjamin, Li, Shengchao, Liu, Zhen, Maldonado, Juan P. A., Marvinney, Claire, Oo, Hein Zay Yar, Pai, Yun-Yi, Pooser, Raphael, Qin, Juehang, Sparmann, Tobias J., Taylor, Jacob M., Tian, Hao, and Tunnell, Christopher
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High Energy Physics - Experiment ,Astrophysics - Cosmology and Nongalactic Astrophysics ,High Energy Physics - Phenomenology - Abstract
The absence of clear signals from particle dark matter in direct detection experiments motivates new approaches in disparate regions of viable parameter space. In this Snowmass white paper, we outline the Windchime project, a program to build a large array of quantum-enhanced mechanical sensors. The ultimate aim is to build a detector capable of searching for Planck mass-scale dark matter purely through its gravitational coupling to ordinary matter. In the shorter term, we aim to search for a number of other physics targets, especially some ultralight dark matter candidates. Here, we discuss the basic design, open R&D challenges and opportunities, current experimental efforts, and both short- and long-term physics targets of the Windchime project., Comment: 8 pages, 3 figures. Contribution to the Snowmass 2021 proceedings (Cosmic Frontier working groups 1 and 2 - particle and wave-like dark matter)
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- 2022
40. Snowmass2021 Cosmic Frontier White Paper: Rubin Observatory after LSST
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Blum, Bob, Digel, Seth W., Drlica-Wagner, Alex, Habib, Salman, Heitmann, Katrin, Ishak, Mustapha, Jha, Saurabh W., Kahn, Steven M., Mandelbaum, Rachel, Marshall, Phil, Newman, Jeffrey A., Roodman, Aaron, and Stubbs, Christopher W.
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Astrophysics - Cosmology and Nongalactic Astrophysics ,High Energy Physics - Phenomenology - Abstract
The Vera C. Rubin Observatory will begin the Legacy Survey of Space and Time (LSST) in 2024, spanning an area of 18,000 square degrees in six bands, with more than 800 observations of each field over ten years. The unprecedented data set will enable great advances in the study of the formation and evolution of structure and exploration of physics of the dark universe. The observations will hold clues about the cause for the accelerated expansion of the universe and possibly the nature of dark matter. During the next decade, LSST will be able to confirm or dispute if tensions seen today in cosmological data are due to new physics. New and unexpected phenomena could confirm or disrupt our current understanding of the universe. Findings from LSST will guide the path forward post-LSST. The Rubin Observatory will still be a uniquely powerful facility even then, capable of revealing further insights into the physics of the dark universe. These could be obtained via innovative observing strategies, e.g., targeting new probes at shorter timescales than with LSST, or via modest instrumental changes, e.g., new filters, or through an entirely new instrument for the focal plane. This White Paper highlights some of the opportunities in each scenario from Rubin observations after LSST., Comment: Contribution to Snowmass 2021
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- 2022
41. Snowmass2021 Cosmic Frontier White Paper: Cosmological Simulations for Dark Matter Physics
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Banerjee, Arka, Boddy, Kimberly K., Cyr-Racine, Francis-Yan, Erickcek, Adrienne L., Gilman, Daniel, Gluscevic, Vera, Kim, Stacy, Lehmann, Benjamin V., Mao, Yao-Yuan, Mocz, Philip, Munshi, Ferah, Nadler, Ethan O., Necib, Lina, Parikh, Aditya, Peter, Annika H. G., Sales, Laura, Vogelsberger, Mark, and Wright, Anna C.
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Astrophysics - Cosmology and Nongalactic Astrophysics ,Astrophysics - Astrophysics of Galaxies ,High Energy Physics - Phenomenology - Abstract
Over the past several decades, unexpected astronomical discoveries have been fueling a new wave of particle model building and are inspiring the next generation of ever-more-sophisticated simulations to reveal the nature of Dark Matter (DM). This coincides with the advent of new observing facilities coming online, including JWST, the Rubin Observatory, the Nancy Grace Roman Space Telescope, and CMB-S4. The time is now to build a novel simulation program to interpret observations so that we can identify novel signatures of DM microphysics across a large dynamic range of length scales and cosmic time. This white paper identifies the key elements that are needed for such a simulation program. We identify areas of growth on both the particle theory side as well as the simulation algorithm and implementation side, so that we can robustly simulate the cosmic evolution of DM for well-motivated models. We recommend that simulations include a fully calibrated and well-tested treatment of baryonic physics, and that outputs should connect with observations in the space of observables. We identify the tools and methods currently available to make predictions and the path forward for building more of these tools. A strong cosmic DM simulation program is key to translating cosmological observations to robust constraints on DM fundamental physics, and provides a connection to lab-based probes of DM physics., Comment: Contribution to Snowmass 2021
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- 2022
42. Snowmass2021 Cosmic Frontier White Paper: Fundamental Physics and Beyond the Standard Model
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Berti, Emanuele, Cardoso, Vitor, Haiman, Zoltán, Holz, Daniel E., Mottola, Emil, Mukherjee, Suvodip, Sathyaprakash, Bangalore, Siemens, Xavier, and Yunes, Nicolás
- Subjects
High Energy Physics - Phenomenology ,General Relativity and Quantum Cosmology ,High Energy Physics - Theory - Abstract
Gravitational wave detectors are formidable tools to explore strong-field gravity, especially black holes and neutron stars. These compact objects are extraordinarily efficient at producing electromagnetic and gravitational radiation. As such, they are ideal laboratories for fundamental physics and have an immense discovery potential. The detection of black hole binaries by third-generation Earth-based detectors, space-based detectors and pulsar timing arrays will provide exquisite tests of general relativity. Loud "golden" events and extreme mass-ratio inspirals can strengthen the observational evidence for horizons by mapping the exterior spacetime geometry, inform us on possible near-horizon modifications, and perhaps reveal a breakdown of Einstein's gravity. Measurements of the black-hole spin distribution and continuous gravitational-wave searches can turn black holes into efficient detectors of ultralight bosons across ten or more orders of magnitude in mass. A precise monitoring of the phase of inspiralling binaries can constrain the existence of additional propagating fields and characterize the environment in which the binaries live, bounding the local dark matter density and properties. Gravitational waves from compact binaries will probe general relativity and fundamental physics in previously inaccessible regimes, and allow us to address fundamental issues in our current understanding of the cosmos., Comment: Contribution to Snowmass 2021 - Cosmic Frontier (CF07: Cosmic probes of fundamental physics). 24 pages, 4 figures. v2: added list of endorsers and references to related White Papers, minor corrections
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- 2022
43. Neutrino Self-Interactions: A White Paper
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Berryman, Jeffrey M., Blinov, Nikita, Brdar, Vedran, Brinckmann, Thejs, Bustamante, Mauricio, Cyr-Racine, Francis-Yan, Das, Anirban, de Gouvêa, André, Denton, Peter B., Dev, P. S. Bhupal, Dutta, Bhaskar, Esteban, Ivan, Fiorillo, Damiano F. G., Gerbino, Martina, Ghosh, Subhajit, Ghosh, Tathagata, Grohs, Evan, Han, Tao, Hannestad, Steen, Hostert, Matheus, Huber, Patrick, Hyde, Jeffrey, Kelly, Kevin J., Kling, Felix, Liu, Zhen, Lattanzi, Massimiliano, Loverde, Marilena, Pandey, Sujata, Saviano, Ninetta, Sen, Manibrata, Shoemaker, Ian M., Tangarife, Walter, Zhang, Yongchao, and Zhang, Yue
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High Energy Physics - Phenomenology ,Astrophysics - High Energy Astrophysical Phenomena ,High Energy Physics - Experiment ,High Energy Physics - Theory - Abstract
Neutrinos are the Standard Model (SM) particles which we understand the least, often due to how weakly they interact with the other SM particles. Beyond this, very little is known about interactions among the neutrinos, i.e., their self-interactions. The SM predicts neutrino self-interactions at a level beyond any current experimental capabilities, leaving open the possibility for beyond-the-SM interactions across many energy scales. In this white paper, we review the current knowledge of neutrino self-interactions from a vast array of probes, from cosmology, to astrophysics, to the laboratory. We also discuss theoretical motivations for such self-interactions, including neutrino masses and possible connections to dark matter. Looking forward, we discuss the capabilities of searches in the next generation and beyond, highlighting the possibility of future discovery of this beyond-the-SM physics., Comment: Editors: Nikita Blinov, Mauricio Bustamante, Kevin J. Kelly, Yue Zhang. 29 pages, 16 figures, plus references. Contribution to Snowmass 2021
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- 2022
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44. TRSM Benchmark Planes -- Snowmass White Paper
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Robens, Tania
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High Energy Physics - Phenomenology - Abstract
In this whitepaper, I briefly review the Benchmark Planes in the Two-Real-Singlet Model (TRSM), a model that enhances the Standard Model (SM) scalar sector by two real singlets that obey a $\mathbb{Z}_2\,\otimes\,\mathbb{Z}_2'$ symmetry. In this model, all fields acquire a vacuum expectation value, such that the model contains in total 3 CP-even neutral scalars that can interact with each other. All interactions with SM-like particles are inherited from the SM-like doublet via mixing. I remind the readers of the previously proposed benchmark planes, and briefly discuss possible production at future Higgs factories., Comment: 14 pages, 7 figures; contribution to Snowmass 2021
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- 2022
45. Signal strength and W-boson mass measurements as a probe of the electro-weak phase transition at colliders -- Snowmass White Paper
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Papaefstathiou, Andreas, Robens, Tania, and White, Graham
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High Energy Physics - Phenomenology - Abstract
We consider an extension of the scalar sector of the Standard Model (SM) by an additional gauge singlet, which mixes with a part of the SM-like Higgs doublet. Within this model, parameter-space regions exist that can lead to a strong first-order electro-weak phase transition, a necessary condition for electro-weak baryogenesis. We discuss how such regions of the parameter space can be tested using the SM-like Higgs boson's signal strength measurements, as well as precision observables, such as e.g. the W-boson mass, at current and future colliders., Comment: 8 pages, 1 figure; contribution to Snowmass 2021. Minor correction to v1
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- 2022
46. Snowmass White Paper: Generalized Symmetries in Quantum Field Theory and Beyond
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Cordova, Clay, Dumitrescu, Thomas T., Intriligator, Kenneth, and Shao, Shu-Heng
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High Energy Physics - Theory ,High Energy Physics - Phenomenology - Abstract
Symmetry plays a central role in quantum field theory. Recent developments include symmetries that act on defects and other subsystems, and symmetries that are categorical rather than group-like. These generalized notions of symmetry allow for new kinds of anomalies that constrain dynamics. We review some transformative instances of these novel aspects of symmetry in quantum field theory, and give a broad-brush overview of recent applications., Comment: Contribution to 2022 Snowmass Summer Study. 10 pages + bibliography
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- 2022
47. Naturalness: A Snowmass White Paper
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Craig, Nathaniel
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High Energy Physics - Phenomenology ,High Energy Physics - Theory - Abstract
We assess the state of naturalness in high-energy physics and summarize recent approaches to the three major naturalness problems: the cosmological constant problem, the electroweak hierarchy problem, and the strong CP problem., Comment: 43 pages, contribution to Snowmass 2021
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- 2022
48. Snowmass White Paper: prospects for the measurement of top-quark couplings
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Durieux, Gauthier, Camacho, Abel Gutiérrez, Mantani, Luca, Miralles, Víctor, López, Marcos Miralles, Llácer, María Moreno, Poncelet, René, Vryonidou, Eleni, and Vos, Marcel
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High Energy Physics - Phenomenology - Abstract
In this contribution to the 2021 Snowmass community planning exercise that informs the American strategy for particle physics, we present the prospects for measurements of the top-quark couplings at future colliders. Projections are presented for the high luminosity phase of the Large Hadron Collider and a future Higgs/electroweak/top factory electron-positron collider. Results are presented for the expected bounds on Wilson coefficients of the relevant SMEFT operators from a global fit to the top physics sector., Comment: Contribution Snowmass 2021
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- 2022
49. Snowmass 2021 White Paper: Observational Signatures of Quantum Gravity
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Zurek, Kathryn M.
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General Relativity and Quantum Cosmology ,High Energy Physics - Phenomenology ,High Energy Physics - Theory - Abstract
This short review is intended as a colloquium-level summary, for the Snowmass 2021 process, on recent theoretical results on infrared observables in quantum gravity. We rely on simple physical arguments, most notably a random walk intuition, to show how effects of quantum gravity in the ultraviolet (at the Planck length $\ell_p \approx 10^{-35} \mbox{ m}$) may integrate into the infrared when the large measurement length scale $L$ enters into the observable. A quantum uncertainty at lightsheet horizons would give rise to an accumulated effect of size $\delta L^2 \simeq \ell_p L/4 \pi$. We discuss how the random walk intuition falls out from more formal calculations, such as from AdS/CFT, from the dimensional reduction of the Einstein-Hilbert action to dilaton gravity, from multiple gravitational shockwaves generated by vacuum energy fluctuations, as well as from an effective description of gravity as a fluid. We overview experimental prospects for measuring this effect with a simple Michelson interferometer utilizing many of the tools developed for gravitational wave observatories., Comment: 16 pages, 3 figures
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- 2022
50. Neutrino Flavor Model Building and the Origins of Flavor and CP Violation: A Snowmass White Paper
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Almumin, Yahya, Chen, Mu-Chun, Cheng, Murong, Knapp-Perez, Victor, Li, Yulun, Mondol, Adreja, Ramos-Sanchez, Saul, Ratz, Michael, and Shukla, Shreya
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High Energy Physics - Phenomenology ,High Energy Physics - Theory - Abstract
The neutrino sector offers one of the most sensitive probes of new physics beyond the Standard Model of Particle Physics. The mechanism of neutrino mass generation is still unknown. The observed suppression of neutrino masses hints at a large scale, conceivably of the order of the scale of a Grand Unified Theory (GUT), a unique feature of neutrinos that is not shared by the charged fermions. The origin of neutrino masses and mixing is part of the outstanding puzzle of fermion masses and mixings, which is not explained in the SM. Flavor model building for both quark and lepton sectors is important in order to gain a better understanding of the origin of the structure of mass hierarchy and flavor mixing, which constitute the dominant fraction of the SM parameters. Recent activities in neutrino flavor model building based on non-Abelian discrete flavor symmetries and modular flavor symmetries have been shown to be a promising direction to explore. The emerging models provide a framework that has a significantly reduced number of undetermined parameters in the flavor sector. Model building based on non-Abelian discrete flavor symmetries and their modular variants enables the particle physics community to interpret the current and anticipated upcoming data from neutrino experiments. Pursuit of flavor model building based on such frameworks can also provide connections to possible UV completions, in particular to string theory. We emphasize the importance of constructing models in which the uncertainties of theoretical predictions are smaller than, or at most compatible with, the error bars of measurements in neutrino experiments., Comment: 24 pages, 7 figures, Contribution to Snowmass 2021
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- 2022
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