Search for narrow high-mass resonances in radiative decays of the Z0

Adeva, B.; Адриани, О.; Aguilar-Benı́tez, M.; Akbari, H.; Alcaraz, J.; Aloisio, A.; Alverson, G.; Alviggi, M. G.; An, Q.; Anderhub, H.; Anderson, A.L.; Andreev, V.; Angelov, T.; Antonov, L.; Antreasyan, D.; Arce, P.; Arefiev, A.; Azemoon, T.; Aziz, T.; Baba, P.V.K.S.; Bagnaia, P.; Bakken, J. A.; Baksay, L.; Ball, R. C.; Banerjee, S.; Bao, J.; Barone, L.; Bay, A.; Becker, U.; Behrens, J.; Beingessner, S.; Bencze, G.; Berdugo, J.; Berges, P.; Bertucci, B.; Betev, B.L.; Biland, A.; Bizzarri, R.; Blaising, J. J.; Blömeke, P.; Blumenfeld, B.; Bobbink, G. J.; Bocciolini, M.; Böck, R.; Böhm, A.; Borgia, B.; Bourilkov, D.; Bourquin, M.; Boutigny, D.; Bouwens, B.; Branson, J. G.; Brock, I. C.; Bruyant, F.; Buisson, Christine; Bujak, A.; Burger, J. D.; Burq, J.P.; Busenitz, J.; Cai, X.; Capell, M.; Carbonara, F.; Cardenal, P.; Carminati, F.; Cartacci, A. M.; Cerrada, M.; Cesaroni, F.; Chang, Y. H.; Chaturvedi, U. K.; Chemarin, M.; Chen, A.; Chen, C.; Chen, G.M.; Chen, H.F.; Chen, H.S.; Chen, M.; Chen, M.L.; Chen, W.Y.; Chiefari, G.; Chien, C. Y.; Chollet, F.; Civinini, C.; Clare, I.; Clare, R.; Cohn, H. O.; Coignet, G.; Colino, N.; Commichau, V.; Conforto, G.; Contin, A.; Crijns, F.; Cui, X.; Dai, T.; D’Alessandro, R.; Asmundis, R. de; Degré, A.; Deiters, K.; Dénes, E.; Denes, P.; DeNotaristefani, F.; Dhina, M.; DiBitonto, D.; Diemoz, M.; Diez-Hedo, F.; Dimitrov, H.R.; Dionisi, C.; Divià, R.; Dova, M. T.; Drago, E.; Driever, T.; Duchesneau, D.; Duinker, P.; Durán, I.; Mamouni, H. El; Engler, A.; Eppling, F. J.; Erné, F.C.; Extermann, P.; Fabbretti, R.; Faber, G.; Fabre, Michel; Falciano, S.; Fan, Q.; Fan, Saijun; Fackler, Oliver T.; Fay, J.; Fehlmann, J.; Ferguson, T.; Fernández, G.; Ferroni, F.; Fesefeldt, H.; Field, J. H.; Filthaut, F.; Finocchiaro, G.; Fisher, P. H.; Forconì, G.; Foreman, T.; Freudenreich, K.; Friebel, W.; Fukushima, M.; Gailloud, M.; Galaktionov, Yu.; Gallo, E.; Ganguli, S. N.; Garcı́a-Abia, P.; Gau, S. S.; Gelé, D.; Gentile, S.; Glaubman, M.; Goldfarb, S.; Gong, Z. F.; González, E.; Gordeev, A.; Göttlicher, P.; Goujon, D.; Gratta, G.; Grinnell, C.; Gruenewald, M. W.; Guanziroli, M.; Guo, J.; Gurtu, A.; Gustafson, H. R.; Gutay, L.; Haan, H.; Hasan, A.; Hauschildt, D.; He, Changda; Hebbeker, T.; Hebert, M.; Herten, G.; Herten, U.; Hervé, A.; Hilgers, K.; Hofer, H.; Hoorani, H. R.; Hsu, L.; Hu, G.; Ille, B.; Ilyas, M. M.; Innocente, V.; Isiksal, E.; Janßen, H.; Jin, B. N.; Jones, L. W.; Kasser, A.; Khan, R. A.; Kamyshkov, Yu.; Karyotakis, Y.; Kaur, M.; Khokhar, S.; Хозе, В. А.; Kienzle‐Focacci, M. N.; Kinnison, W. W.; Kirkby, D.; Kittel, W.; Klimentov, A.; König, A.; Kornadt, O.; Koutsenko, V.; Kraemer, R.W.; Krämer, T.; Krastev, V.R.; Krenz, W.; Krizmanic, John F.; Kumar, Krishna; Kumar, V.; Kunin, A.; Lalieu, V.; Landi, G.; Lanius, K.; Lanske, D.; Lanzano, S.; Lebrun, P.; Lecomte, P.; Lecoq, P.; Coultre, P. Le; Lee, D.; Leedom, I.; Goff, J. M. Le; Leistam, L.; Leiste, R.; Lenti, M.; Leonardi, E.; Lettry, J.; Levchenko, P.; Leytens, X.; Li, C.; Li, H.T.; Li, J.F.; Li, L.; Li, P.J.; Li, Q.; Li, X.G.; Liao, Jiajun; Lin, Z.; Linde, F.L.; Lindemann, B.; Linnhöfer, D.; Liu, R.; Liu, Y.; Lohmann, W.; Longo, E.; Lu, Y. S.; Lubbers, J.M.; Lübelsmeyer, K.; Luci, C.; Luckey, D.; Ludovici, L.; Lue, X.; Luminari, L.; Wen-Gan, Ma; MacDermott, M.; Magahiz, R.; Maire, M.; Malhotra, P.K.; Malik, R. P.; Малинин, А.; Mañá, C.; Mao, Dan; Mao, Yajun; Maolinbay, M.; Marchesini, P.; Marchionni, A.; Martin, B.; Martin, J. P.; Martínez-Laso, L.; Marzano, F.; Massaro, G.; Matsuda, Takeshi; Mazumdar, K.; McBride, P.; McMahon, T. R.; McNally, D.; Meinholz, Th.; Merk, M.; Merola, L.; Meschini, M.; Metzger, W. J.; Mei, Yong; Mills, G. B.; Mir, Y.; Mirabelli, G.; Mnich, J.; Möller, Martin; Monteleoni, B.; Morand, G.; Morand, R.; Morganti, S.; Moulai, N. E.; Mount, R.; Müller, S.; Nagy, E.; Napolitano, M.; Newman, H. B.; Neyer, C.; Niaz, M. A.; Niessen, L.; Nowak, H.; Pandoulas, D.; Plášil, F.; Passaleva, G.; Paternoster, G.; Patricelli, S.; Pei, Y. J.; Perret-Gallix, D.; Perrier, J.; Pevsner, A.; Pieri, M.; Piroué, P.; Plyaskin, V.; Pohl, M.; Pojidaev, V.; Produit, N.; Oian, J.M.; Qureshi, K.N.; Raghavan, R.; Rahal-Callot, G.; Razis, P. A.; Read, K. F.; Ren, D.; Ren, Z.; Reucroft, S.; Ricker, A.; Rind, O.; Rippich, C.; Rizvi, Hasan; Roe, B.P.; Röhner, M.; Röhner, S.; Romero, L.; Rose, J.; Rosier‐Lees, S.; Rosmalen, R.; Rosselet, Ph.; Rubbia, A.; Rubio, J. A.; Rubio, María Teresa Maza; Ruckstuhl, W.; Rykaczewski, H.; Sachwitz, M.; Salicio, J.; Sanders, G. S.; Sarakinos, M. S.; Sartorelli, G.; Sauvage, G.; Savin, A.; Schegelsky, V. A.; Schmiemann, K.; Schmitz, D.; Schmitz, P.; Schneegans, M.; Schopper, H.; Schotanus, D. J.; Shotkin, S.; Schreiber, H. J.; Schulte, R.; Schulte, Stefan; Schultze, K.; Schütte, J.; Schwenke, J.; Schwering, G.; Sciacca, C.; Scott, I.; Sehgal, R.; Seiler, P.G.; Sens, J.C.; Sheer, I.; Shen, D. Z.; Shevchenko, V.; Shevchenko, S.; Shi, Xiangdong; Shmakov, K.; Shoutko, V.; Shumilov, E.; Smirnov, N.; Soderstrom, E.; Sopczak, A.; Spartiotis, C.; Spickermann, T.; Spiess, B.; Спиллантини, П.; Starosta, R.; Steuer, M.; Stickland, D.; Stocozzi, F.; Stoeffl, W.; Stone, Howard A.; Strauch, K.; Stringfellow, B.; Sudhakar, K.; Sultanov, G.; Summer, R.L.; Sun, L. Z.; Suter, H.; Sutton, R.B.; Swain, J.; Syed, A.A.; Tang, X. W.; Tarkovsky, E.; Taylor, L.; Timmermans, C.; Ting, Samuel C.C.; Ting, S. M.; Tong, Y.P.; Tonisch, F.; Tonutti, M.; Tonwar, S. C.; Töth, J.; Trowitzch, G.; Tully, C.; Tung, K. L.; Ulbricht, J.; Urbán, László; Uwer, U.; Valente, E.; Walle, R. T. Van de; Vetlitsky, I.; Viertel, G.; Vikas, P.; Vikas, U.; Vivargent, M.; Vogel, H.; Vogt, H.; Dardel, G. Von; Vorobiev, I.; Vorobyov, A. A.; Vuilleumier, Laurent; Wadha, M.; Wallraff, W.; Wang, C.R.; Wang, G.H.; Wang, J.H.; Wang, Q.F.; Wang, X.L.; Wang, Y.F.; Wang, Z.; Wang, Z.M.; Weber, A.; Weber, J.; Weill, R.; Wenaus, T.; Wenninger, J.; White, M. J.; Willmott, C.; Wittgenstein, F.; Wright, D.; Wu, Rui; Wu, S. L.; Wu, S. X.; Wu, Y.; Wysłouch, B.; Xie, Y.; Xu, Y.D.; Xu, Z. Z.; Xue, Z.; Yan, D.S.; Yan, Xu; Yang, B. Z.; Yang, C. G.; Yang, G.; Yang, K.S.; Yang, Qiang; Yang, Z.; Ye, C.H.; Ye, J.B.; Ye, Q.; Yeh, S. C.; Yin, Z.W.; You, J. M.; Yzerman, M.; Zaccardelli, C.; Zehnder, L.; Zemp, P.; Zeng, M.; Zeng, Y.; Zhang, D.H.; Zhang, Z.P.; Zhou, Jianfeng; Zhu, R. Y.; Zhuang, H.L.; Zichichi, A.

doi:10.1016/0370-2693(91)90659-e

Cited by 13 publications

(13 citation statements)

References 20 publications

(5 reference statements)

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“…The constants c i are anomaly coefficients which depend on the number of degrees of freedom chiral under the U (1) symmetry and carrying a non-zero charge under the SM gauge group. 2 1 As an example the LEP limit on BR(Z → γa) is 1.7 · 10 −5 from 36.9 pb −1 of data if a is a diphoton resonance [36] and 4.7 · 10 −4 from 5.5 pb −1 of data if a is a dijet resonance [37]. 2 If the SM fermions and the Higgs doublet are uncharged under the U (1) symmetry, the couplings of the pNGB to them arise only from loops of SM gauge bosons and can safely be neglected.…”

Section: Resultsmentioning

confidence: 99%

New axion searches at flavor factories

Vidal¹,

Mariotti

Redigolo

et al. 2019

J. High Energ. Phys.

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We assess the impact of searches at flavor factories for new neutral resonances that couple to both photons and gluons. These are well motivated by "heavy axion" solutions of the strong CP problem and by frameworks addressing both Dark Matter and the Higgs hierarchy problem. We use LHCb public diphoton data around the Bs mass to derive the current best limit on these resonances for masses between 4.9 and 6.3 GeV. We estimate that a future LHCb dedicated search would test an axion decay constant of O(TeV) for axion masses in the few-to-tens of GeV, being fully complementary to the low mass ATLAS and CMS searches. We also derive the impact of BABAR searches based on Υ decays and the future Belle-II reach.

show abstract

Section: Resultsmentioning

confidence: 99%

New axion searches at flavor factories

Vidal¹,

Mariotti

Redigolo

et al. 2019

J. High Energ. Phys.

View full text Add to dashboard Cite

show abstract

“…If X escapes the detector or decays invisibly, then LEP searches [30,31] for single photons at half the Z energy constrain this branching ratio to be < ∼ 10 −6 . For visible decays, there are published branching ratio limits for X → jet + jet and X → l + l − of < ∼ 3×10 −3 [32] and 5 × 10 −4 [33] respectively, with some improvement in the high mass region [34]. While these limits (from LEP) are not particularly stringent, we expect that the LHC has the capacity to significantly improve them.…”

Section: Axion-like Behaviourmentioning

confidence: 97%

“…However, this weak-isospin breaking in the EFT means that π ± → e ± νX decays, as discussed in section III D, are energy-enhanced. In the model of [9], in which X has dimension-4 couplings to electrons, but not to pions or neutrinos, the induced [50,53,54], B → KX (blue) [45][46][47][48][49], Z → Xγ (red) [30][31][32][33][34], very displaced decays at the CHARM proton beam dump experiment [58], and monojets [98]. The enhanced K → πX decays result in larger X production than computed in naive analyses [59,60].…”

Section: Constraints On Modelsmentioning

confidence: 99%

Dark forces coupled to nonconserved currents

2017

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New light vectors with dimension-4 couplings to Standard Model states have (energy/vector mass) 2 enhanced production rates unless the current they couple to is conserved. These processes allow us to derive new constraints on the couplings of such vectors, that are significantly stronger than the previous literature for a wide variety of models. Examples include vectors with axial couplings to quarks and vectors coupled to currents (such as baryon number) that are only broken by the chiral anomaly. Our new limits arise from a range of processes, including rare Z decays and flavor changing meson decays, and rule out a number of phenomenologically-motivated proposals.

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“…If X decays invisibly, then LEP searches for single photons at half the Z energy [32,33] limit this branching ratio to be < ∼ 10 −6 . The bounds for SM decays of X are less stringent [34][35][36], though the large number of Z bosons produced at hadron colliders should allow enhanced sensitivity to rare Z decays, as we discuss later.…”

Section: Arxiv:170506726v2 [Hep-ph] 25 Mar 2018mentioning

confidence: 99%

New Constraints on Light Vectors Coupled to Anomalous Currents

2017

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We derive new constraints on light vectors coupled to standard model (SM) fermions, when the corresponding SM current is broken by the chiral anomaly. The cancellation of the anomaly by heavy fermions results, in the low-energy theory, in Wess-Zumino-type interactions between the new vector and the SM gauge bosons. These interactions are determined by the requirement that the heavy sector preserves the SM gauge groups and lead to (energy/vector mass)^{2} enhanced rates for processes involving the longitudinal mode of the new vector. Taking the example of a vector coupled to a vector coupled to SM baryon number, Z decays and flavor-changing neutral current meson decays via the new vector can occur with (weak scale/vector mass)^{2} enhanced rates. These processes place significantly stronger coupling bounds than others considered in the literature, over a wide range of vector masses.

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Search for narrow high-mass resonances in radiative decays of the Z0

Cited by 13 publications

References 20 publications

New axion searches at flavor factories

New axion searches at flavor factories

Dark forces coupled to nonconserved currents

New Constraints on Light Vectors Coupled to Anomalous Currents

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