Prof Subir Sarkar

Magnetic monopole search with the full MoEDAL trapping detector in 13 TeV $pp$ collisions interpreted in photon-fusion and Drell-Yan production

(2019)

Authors:

MoEDAL Collaboration, B Acharya, J Alexandre, S Baines, P Benes, B Bergmann, J Bernabéu, A Bevan, H Branzas, M Campbell, S Cecchini, YM Cho, M de Montigny, A De Roeck, JR Ellis, M El Sawy, M Fairbairn, D Felea, M Frank, J Hays, AM Hirt, J Janecek, D-W Kim, A Korzenev, DH Lacarrère, SC Lee, C Leroy, G Levi, A Lionti, J Mamuzic, A Margiotta, N Mauri, NE Mavromatos, P Mermod, M Mieskolainen, L Millward, VA Mitsou, R Orava, I Ostrovskiy, J Papavassiliou, B Parker, L Patrizii, GE Păvălaş, JL Pinfold, V Popa, M Pozzato, S Pospisil, A Rajantie, R Ruiz de Austri, Z Sahnoun, M Sakellariadou, A Santra, S Sarkar, G Semenoff, A Shaa, G Sirri, K Sliwa, R Soluk, M Spurio, M Staelens, M Suk, M Tenti, V Togo, JA Tuszyński, V Vento, O Vives, Z Vykydal, A Wall, IS Zgura

Maser radiation from collisionless shocks: application to astrophysical jets

High Power Laser Science and Engineering Cambridge University Press 7 (2019) e17

Authors:

DC Speirs, K Ronald, ADR Phelps, A Rigby, JE Cross, PM Kozlowski, F Miniati, M Oliver, S Sarkar, Petros Tzeferacos, Gianluca Gregori, Et al.

Abstract:

This paper describes a model of electron energization and cyclotron-maser emission applicable to astrophysical magnetized collisionless shocks. It is motivated by the work of Begelman, Ergun and Rees [Astrophys. J. 625, 51 (2005)] who argued that the cyclotron-maser instability occurs in localized magnetized collisionless shocks such as those expected in blazar jets. We report on recent research carried out to investigate electron acceleration at collisionless shocks and maser radiation associated with the accelerated electrons. We describe how electrons accelerated by lower-hybrid waves at collisionless shocks generate cyclotron-maser radiation when the accelerated electrons move into regions of stronger magnetic fields. The electrons are accelerated along the magnetic field and magnetically compressed leading to the formation of an electron velocity distribution having a horseshoe shape due to conservation of the electron magnetic moment. Under certain conditions the horseshoe electron velocity distribution function is unstable to the cyclotron-maser instability [Bingham and Cairns, Phys. Plasmas 7, 3089 (2000); Melrose, Rev. Mod. Plasma Phys. 1, 5 (2017)].

Spectral Distortions of the CMB as a Probe of Inflation, Recombination, Structure Formation and Particle Physics

(2019)

Authors:

J Chluba, A Kogut, SP Patil, MH Abitbol, N Aghanim, Y Ali-Haimoud, MA Amin, J Aumont, N Bartolo, K Basu, ES Battistelli, R Battye, D Baumann, I Ben-Dayan, B Bolliet, JR Bond, FR Bouchet, CP Burgess, C Burigana, CT Byrnes, G Cabass, DT Chuss, S Clesse, PS Cole, L Dai, P de Bernardis, J Delabrouille, V Desjacques, G de Zotti, JAD Diacoumis, E Dimastrogiovanni, E Di Valentino, J Dunkley, R Durrer, C Dvorkin, J Ellis, HK Eriksen, M Fasiello, D Fixsen, F Finelli, R Flauger, S Galli, J Garcia-Bellido, M Gervasi, V Gluscevic, D Grin, L Hart, C Hernandez-Monteagudo, JC Hill, D Jeong, BR Johnson, G Lagache, E Lee, A Lewis, M Liguori, M Kamionkowski, R Khatri, K Kohri, E Komatsu, KE Kunze, A Mangilli, S Masi, J Mather, S Matarrese, MA Miville-Deschenes, T Montaruli, M Munchmeyer, S Mukherjee, T Nakama, F Nati, A Ota, LA Page, E Pajer, V Poulin, A Ravenni, C Reichardt, M Remazeilles, A Rotti, JA Rubino-Martin, A Sarkar, S Sarkar, G Savini, D Scott, PD Serpico, J Silk, T Souradeep, DN Spergel, AA Starobinsky, R Subrahmanyan, RA Sunyaev, E Switzer, A Tartari, H Tashiro, R Basu Thakur, T Trombetti, B Wallisch, BD Wandelt, IK Wehus, EJ Wollack, M Zaldarriaga, M Zannoni

Search for annihilating dark matter in the Sun with 3 years of IceCube data (vol 77, pg 146, 2017)

EUROPEAN PHYSICAL JOURNAL C 79:3 (2019) ARTN 214

Authors:

MG Aartsen, M Ackermann, J Adams, JA Aguilar, M Ahlers, M Ahrens, D Altmann, K Andeen, T Anderson, I Ansseau, G Anton, M Archinger, C Arguelles, J Auffenberg, S Axani, X Bai, SW Barwick, V Baum, R Bay, JJ Beatty, J Becker Tjus, K-H Becker, S BenZvi, D Berley, E Bernardini, A Bernhard, DZ Besson, G Binder, D Bindig, M Bissok, E Blaufuss, S Blot, C Bohm, M Boerner, F Bos, D Bose, S Boeser, O Botner, J Braun, L Brayeur, H-P Bretz, S Bron, A Burgman, T Carver, M Casier, E Cheung, D Chirkin, A Christov, K Clark, L Classen, S Coenders, GH Collin, JM Conrad, DF Cowen, R Cross, M Day, JPAM de Andre, C De Clercq, E del Pino Rosendo, H Dembinski, S De Ridder, P Desiati, KD de Vries, G de Wasseige, M de With, T DeYoung, JC Diaz-Velez, V di Lorenzo, H Dujmovic, JP Dumm, M Dunkman, B Eberhardt, T Ehrhardt, B Eichmann, P Eller, S Euler, PA Evenson, S Fahey, AR Fazely, J Feintzeig, J Felde, K Filimonov, C Finley, S Flis, C-C Foesig, A Franckowiak, E Friedman, T Fuchs, TK Gaisser, J Gallagher, L Gerhardt, K Ghorbani, W Giang, L Gladstone, T Glauch, T Gluesenkamp, A Goldschmidt, JG Gonzalez, D Grant, Z Griffith, C Haack, A Hallgren, F Halzen, E Hansen, T Hansmann, K Hanson, D Hebecker, D Heereman, K Helbing, R Hellauer, S Hickford, J Hignight, GC Hill, KD Hoffman, R Hoffmann, K Hoshina, F Huang, M Huber, K Hultqvist, S In, A Ishihara, E Jacobi, GS Japaridze, M Jeong, K Jero, BJP Jones, W Kang, A Kappes, T Karg, A Karle, U Katz, M Kauer, A Keivani, JL Kelley, A Kheirandish, J Kim, M Kim, T Kintscher, J Kiryluk, T Kittler, SR Klein, G Kohnen, R Koirala, H Kolanoski, R Konietz, L Koepke, C Kopper, S Kopper, DJ Koskinen, M Kowalski, K Krings, M Kroll, G Krueckl, C Krueger, J Kunnen, S Kunwar, N Kurahashi, T Kuwabara, M Labare, JL Lanfranchi, MJ Larson, F Lauber, D Lennarz, M Lesiak-Bzdak, M Leuermann, L Lu, J Lunemann, J Madsen, G Maggi, KBM Mahn, S Mancina, M Mandelartz, R Maruyama, K Mase, R Maunu, F McNally, K Meagher, M Medici, M Meier, A Meli, T Menne, G Merino, T Meures, S Miarecki, T Montaruli, M Moulai, R Nahnhauer, U Naumann, G Neer, H Niederhausen, SC Nowicki, DR Nygren, A Obertacke Pollmann, A Olivas, A O'Murchadha, T Palczewski, H Pandya, DV Pankova, P Peiffer, Oe Penek, JA Pepper, C Perez de los Heros, D Pieloth, E Pinat, PB Price, GT Przybylski, M Quinnan, C Raab, L Raedel, M Rameez, K Rawlins, R Reimann, B Relethford, M Relich, E Resconi, W Rhode, M Richman, B Riedel, S Robertson, M Rongen, C Rott, T Ruhe, D Ryckbosch, D Rysewyk, L Sabbatini, SE Sanchez Herrera, A Sandrock, J Sandroos, S Sarkar, K Satalecka, P Schlunder, T Schmidt, S Schoenen, S Schoeneberg, L Schumacher, D Seckel, S Seunarine, D Soldin, M Song, GM Spiczak, C Spiering, T Stanev, A Stasik, J Stettner, A Steuer, T Stezelberger, RG Stokstad, A Stossl, R Strom, NL Strotjohann, GW Sullivan, M Sutherland, H Taavola, I Taboada, J Tatar, F Tenholt, S Ter-Antonyan, A Terliuk, G Tesic, S Tilav, PA Toale, MN Tobin, S Toscano, D Tosi, M Tselengidou, A Turcati, E Unger, M Usner, J Vandenbroucke, N van Eijndhoven, S Vanheule, M van Rossem, J van Santen, M Vehring, M Voge, E Vogel, M Vraeghe, C Walck, A Wallace, M Wallraff, N Wandkowsky, Ch Weaver, MJ Weiss, C Wendt, S Westerhoff, BJ Whelan, S Wickmann, K Wiebe, CH Wiebusch, L Wille, DR Williams, L Wills, M Wolf, TR Wood, E Woolsey, K Woschnagg, DL Xu, XW Xu, Y Xu, JP Yanez, G Yodh, S Yoshida, M Zoll, IceCube Collaboration

Science with the Cherenkov Telescope Array

World Scientific (2019)

Authors:

BS Acharya, I Agudo, Rafael Batista, Thomas Armstrong, Garret Cotter, Andrea Franco, Paul Morris, Subir Sarkar, Jason J Watson

Abstract:

The Cherenkov Telescope Array, CTA, will be the major global observatory for very high energy gamma-ray astronomy over the next decade and beyond. The scientific potential of CTA is extremely broad: from understanding the role of relativistic cosmic particles to the search for dark matter. CTA is an explorer of the extreme universe, probing environments from the immediate neighbourhood of black holes to cosmic voids on the largest scales. Covering a huge range in photon energy from 20 GeV to 300 TeV, CTA will improve on all aspects of performance with respect to current instruments. The observatory will operate arrays on sites in both hemispheres to provide full sky coverage and will hence maximize the potential for the rarest phenomena such as very nearby supernovae, gamma-ray bursts or gravitational wave transients. With 99 telescopes on the southern site and 19 telescopes on the northern site, flexible operation will be possible, with sub-arrays available for specific tasks. CTA will have important synergies with many of the new generation of major astronomical and astroparticle observatories. Multi-wavelength and multi-messenger approaches combining CTA data with those from other instruments will lead to a deeper understanding of the broad-band non-thermal properties of target sources. The CTA Observatory will be operated as an open, proposal-driven observatory, with all data available on a public archive after a pre-defined proprietary period. Scientists from institutions worldwide have combined together to form the CTA Consortium. This Consortium has prepared a proposal for a Core Programme of highly motivated observations. The programme, encompassing approximately 40% of the available observing time over the first ten years of CTA operation, is made up of individual Key Science Projects (KSPs), which are presented in this document.