参考文献:1. Farina, M, Pappadopulo, D, Strumia, A (2013) A modified naturalness principle and its experimental tests. JHEP 08: pp. 022 2. Fatelo, JP, Gerard, JM, Hambye, T, Weyers, J (1995) Symmetry breaking induced by top loops. Phys. Rev. Lett. 74: pp. 492 3/PhysRevLett.74.492" target="_blank" title="It opens in new window">CrossRef 3. Hambye, T (1996) Symmetry breaking induced by top quark loops from a model without scalar mass. Phys. Lett. B 371: pp. 87 370-2693(95)01570-1" target="_blank" title="It opens in new window">CrossRef 4. Hempfling, R (1996) The next-to-minimal Coleman-Weinberg model. Phys. Lett. B 379: pp. 153 370-2693(96)00446-7" target="_blank" title="It opens in new window">CrossRef 5. Vissani, F (1998) Do experiments suggest a hierarchy problem?. Phys. Rev. D 57: pp. 7027 6. P.H. Frampton and C. Vafa, / Conformal approach to particle phenomenology, 3226" class="a-plus-plus">hep-th/9903226 [3226" class="a-plus-plus">INSPIRE]. 7. Meissner, KA, Nicolai, H (2007) Conformal symmetry and the standard model. Phys. Lett. B 648: pp. 312 3.023" target="_blank" title="It opens in new window">CrossRef 8. Chang, W-F, Ng, JN, Wu, JMS (2007) Shadow Higgs from a scale-invariant hidden U(1)(s) model. Phys. Rev. D 75: pp. 115016 9. Foot, R, Kobakhidze, A, Volkas, RR (2007) Electroweak Higgs as a pseudo-Goldstone boson of broken scale invariance. Phys. Lett. B 655: pp. 156 CrossRef 10. Foot, R, Kobakhidze, A, McDonald, KL, Volkas, RR (2008) A solution to the hierarchy problem from an almost decoupled hidden sector within a classically scale invariant theory. Phys. Rev. D 77: pp. 035006 11. Iso, S, Okada, N, Orikasa, Y (2009) The minimal B-L model naturally realized at TeV scale. Phys. Rev. D 80: pp. 115007 12. Shaposhnikov, M, Wetterich, C (2010) Asymptotic safety of gravity and the Higgs boson mass. Phys. Lett. B 683: pp. 196 CrossRef 13. Iso, S, Orikasa, Y (2013) TeV scale B-L model with a flat Higgs potential at the Planck scale 鈥?in view of the hierarchy problem. PTEP 2013: pp. 023B08 14. Hur, T, Ko, P (2011) Scale invariant extension of the standard model with strongly interacting hidden sector. Phys. Rev. Lett. 106: pp. 141802 3/PhysRevLett.106.141802" target="_blank" title="It opens in new window">CrossRef 15. M. Shaposhnikov, / Asymptotic safety of gravity and the Higgs-boson mass, / Theor. Math. Phys. 170 (2012) 229 [ / Teor. Mat. Fiz. 170 (2012) 280] [INSPIRE]. 16. Englert, C, Jaeckel, J, Khoze, VV, Spannowsky, M (2013) Emergence of the electroweak scale through the Higgs portal. JHEP 04: pp. 060 3)060" target="_blank" title="It opens in new window">CrossRef 17. Chun, EJ, Jung, S, Lee, HM (2013) Radiative generation of the Higgs potential. Phys. Lett. B 725: pp. 158 3.06.055" target="_blank" title="It opens in new window">CrossRef 18. Heikinheimo, M, Racioppi, A, Raidal, M, Spethmann, C, Tuominen, K (2014) Physical Naturalness and Dynamical Breaking of Classical Scale Invariance. Mod. Phys. Lett. A 29: pp. 1450077 32314500771" target="_blank" title="It opens in new window">CrossRef 19. Hambye, T, Strumia, A (2013) Dynamical generation of the weak and Dark Matter scale. Phys. Rev. D 88: pp. 055022 20. Carone, CD, Ramos, R (2013) Classical scale-invariance, the electroweak scale and vector dark matter. Phys. Rev. D 88: pp. 055020 21. Farzinnia, A, He, H-J, Ren, J (2013) Natural electroweak symmetry breaking from scale invariant Higgs mechanism. Phys. Lett. B 727: pp. 141 3.09.060" target="_blank" title="It opens in new window">CrossRef 22. Foot, R, Kobakhidze, A, McDonald, KL, Volkas, RR (2014) Poincar茅 protection for a natural electroweak scale. Phys. Rev. D 89: pp. 115018 23. Chway, D, Jung, TH, Kim, HD, Dermisek, R (2014) Radiative electroweak symmetry breaking model perturbative all the way to the Planck scale. Phys. Rev. Lett. 113: pp. 051801 3/PhysRevLett.113.051801" target="_blank" title="It opens in new window">CrossRef 24. Holthausen, M, Kubo, J, Lim, KS, Lindner, M (2013) Electroweak and conformal symmetry breaking by a strongly coupled hidden sector. JHEP 12: pp. 076 3)076" target="_blank" title="It opens in new window">CrossRef 25. Hill, CT (2014) Is the Higgs boson associated with Coleman-Weinberg dynamical symmetry breaking?. Phys. Rev. D 89: pp. 073003 26. J. Guo and Z. Kang, / Higgs naturalness and dark matter stability by scale invariance, arXiv:1401.5609 [INSPIRE]. 27. Benic, S, Radovcic, B (2014) Electroweak breaking and Dark Matter from the common scale. Phys. Lett. B 732: pp. 91 3.018" target="_blank" title="It opens in new window">CrossRef 28. Chankowski, PH, Lewandowski, A, Meissner, KA, Nicolai, H (2015) Softly broken conformal symmetry and the stability of the electroweak scale. Mod. Phys. Lett. A 30: pp. 1550006 32315500066" target="_blank" title="It opens in new window">CrossRef 29. Davoudiasl, H, Lewis, IM (2014) Right-handed neutrinos as the origin of the electroweak scale. Phys. Rev. D 90: pp. 033003 30. Allison, K, Hill, CT, Ross, GG (2014) Ultra-weak sector, Higgs boson mass and the dilaton. Phys. Lett. B 738: pp. 191 CrossRef 31. G.M. Pelaggi, / Predictions of a model of weak scale from dynamical breaking of scale invariance, arXiv:1406.4104 [INSPIRE]. 32. Altmannshofer, W, Bardeen, WA, Bauer, M, Carena, M, Lykken, JD (2015) Light dark matter, naturalness and the radiative origin of the electroweak scale. JHEP 01: pp. 032 32" target="_blank" title="It opens in new window">CrossRef 33. R. Foot, A. Kobakhidze and A. Spencer-Smith, / Criticality in the scale invariant standard model (squared), arXiv:1409.4915 [INSPIRE]. 34. M.B. Einhorn and D.R.T. Jones, / Naturalness and dimensional transmutation in classically scale-invariant gravity, 3" class="a-plus-plus">arXiv:1410.8513 [3" class="a-plus-plus">INSPIRE]. 35. Antipin, O, Redi, M, Strumia, A (2015) Dynamical generation of the weak and dark matter scales from strong interactions. JHEP 01: pp. 157 CrossRef 36. Antoniadis, I (1990) A possible new dimension at a few TeV. Phys. Lett. B 246: pp. 377 370-2693(90)90617-F" target="_blank" title="It opens in new window">CrossRef 37. Sundrum, R (2004) Fat euclidean gravity with small cosmological constant. Nucl. Phys. B 690: pp. 302 CrossRef 38. Salvio, A, Strumia, A (2014) Agravity. JHEP 06: pp. 080 CrossRef 39. Litim, DF, Sannino, F (2014) Asymptotic safety guaranteed. JHEP 12: pp. 178 CrossRef 40. Redmond, PJ, Uretsky, JL (1958) Conjecture concerning the properties of nonrenormalizable field theories. Phys. Rev. Lett. 1: pp. 147 3/PhysRevLett.1.147" target="_blank" title="It opens in new window">CrossRef 41. Bogolyubov, NN, Logunov, AA, Shirkov, DV (1960) The method of dispersion relations and perturbation theory Sov. Phys. JETP 37: pp. 574 42. I.M. Suslov, / Renormalization group functions of the 蠒 4 / theory in the strong coupling limit: analytical results, / J. Exp. Theor. Phys. 107 (2008) 413 [ / Zh. Eksp. Teor. Fiz. 134 (2008) 490] [arXiv:1010.4081] [INSPIRE]. 43. Suslov, IM (2009) Exact asymptotics for 尾-function in QED. J. Exp. Theor. Phys. 108: pp. 980 34/S1063776109060089" target="_blank" title="It opens in new window">CrossRef 44. N. Seiberg and E. Witten, / Electric-magnetic duality, monopole condensation and confinement in N = 2 / supersymmetric Yang-Mills theory, / Nucl. Phys. B 426 (1994) 19 [ / Erratum ibid. B 430 (1994) 485] [hep-th/9407087] [INSPIRE]. 45. D.F. Litim, M. Mojaza and F. Sannino, / Vacuum stability of asymptotically safe gauge-Yukawa theories, 3061" class="a-plus-plus">arXiv:1501.03061 [3061" class="a-plus-plus">INSPIRE]. 46. Marques Tavares, G, Schmaltz, M, Skiba, W (2014) Higgs mass naturalness and scale invariance in the UV. Phys. Rev. D 89: pp. 015009 47. Gross, DJ, Wilczek, F (1973) Asymptotically free gauge theories. 1. Phys. Rev. D 8: pp. 3633 48. Gross, DJ, Wilczek, F (1973) Ultraviolet behavior of nonabelian gauge theories. Phys. Rev. Lett. 30: pp. 1343 3/PhysRevLett.30.1343" target="_blank" title="It opens in new window">CrossRef 49. Gross, DJ, Wilczek, F (1974) Asymptotically free gauge theories. 2. Phys. Rev. D 9: pp. 980 50. Politzer, HD (1973) Reliable perturbative results for strong interactions?. Phys. Rev. Lett. 30: pp. 1346 3/PhysRevLett.30.1346" target="_blank" title="It opens in new window">CrossRef 51. Coleman, SR, Gross, DJ (1973) Price of asymptotic freedom. Phys. Rev. Lett. 31: pp. 851 3/PhysRevLett.31.851" target="_blank" title="It opens in new window">CrossRef 52. Cheng, TP, Eichten, E, Li, L-F (1974) Higgs phenomena in asymptotically free gauge theories. Phys. Rev. D 9: pp. 2259 53. Fradkin, ES, Kalashnikov, OK (1976) Asymptotically free SU(5) model of unified interaction. Phys. Lett. B 64: pp. 177 370-2693(76)90324-5" target="_blank" title="It opens in new window">CrossRef 54. O.K. Kalashnikov, / Asymptotically free models of unified interaction, Lebedev-77-206 (1977) [INSPIRE]. 55. Fradkin, ES, Kalashnikov, OK, Konshtein, SE (1978) Asymptotically free E6 model of unified interaction. Lett. Nuovo Cim. 21: pp. 5 CrossRef 56. Kalashnikov, OK (1977) Asymptotically free SU(2) 脳 SU(2) 脳 SU(4) model of unified interaction. Phys. Lett. B 72: pp. 65 370-2693(77)90064-8" target="_blank" title="It opens in new window">CrossRef 57. Pendleton, B, Ross, GG (1981) Mass and mixing angle predictions from infrared fixed points. Phys. Lett. B 98: pp. 291 370-2693(81)90017-4" target="_blank" title="It opens in new window">CrossRef 58. Coleman, SR, Weinberg, EJ (1973) Radiative corrections as the origin of spontaneous symmetry breaking. Phys. Rev. D 7: pp. 1888 59. Callan, CG, Coleman, S (1977) The fate of the false vacuum. 2. First quantum corrections. Phys. Rev. D 16: pp. 1762 60. Isidori, G, Ridolfi, G, Strumia, A (2001) On the metastability of the standard model vacuum. Nucl. Phys. B 609: pp. 387 3213(01)00302-9" target="_blank" title="It opens in new window">CrossRef 61. Espinosa, JR, Giudice, GF, Riotto, A (2008) Cosmological implications of the Higgs mass measurement. JCAP 05: pp. 002 CrossRef 62. Elias-Miro, J (2012) Higgs mass implications on the stability of the electroweak vacuum. Phys. Lett. B 709: pp. 222 3" target="_blank" title="It opens in new window">CrossRef 63. Degrassi, G (2012) Higgs mass and vacuum stability in the standard model at NNLO. JHEP 08: pp. 098 CrossRef 64. Buttazzo, D (2013) Investigating the near-criticality of the Higgs boson. JHEP 12: pp. 089 3)089" target="_blank" title="It opens in new window">CrossRef 65. Frautschi, SC, Kim, J (1982) SU(5) Higgs problem with adjoint + vector representations. Nucl. Phys. B 196: pp. 301 3213(82)90041-4" target="_blank" title="It opens in new window">CrossRef 66. Klimenko, KG (1985) On necessary and sufficient conditions for some Higgs potentials to be bounded from below. Theor. Math. Phys. 62: pp. 58 34825" target="_blank" title="It opens in new window">CrossRef 67. Kannike, K (2012) Vacuum stability conditions from copositivity criteria. Eur. Phys. J. C 72: pp. 2093 3-z" target="_blank" title="It opens in new window">CrossRef 68. D鈥橝mbrosio, G, Giudice, GF, Isidori, G, Strumia, A (2002) Minimal flavor violation: an effective field theory approach. Nucl. Phys. B 645: pp. 155 3213(02)00836-2" target="_blank" title="It opens in new window">CrossRef 69. Buras, AJ, Gemmler, K, Isidori, G (2011) Quark flavour mixing with right-handed currents: an effective theory approach. Nucl. Phys. B 843: pp. 107 CrossRef 70. G. Isidori, / Flavor physics and CP-violation, 302.0661" class="a-plus-plus">arXiv:1302.0661 [302.0661" class="a-plus-plus">INSPIRE]. Search for heavy narrow dilepton resonances in pp collisions at s = 7 $$ \sqrt{s}=7 $$ TeV and s = 8 $$ \sqrt{s}=8 $$ TeV. Phys. Lett. B 720: pp. 63 Search for narrow resonances using the dijet mass spectrum in pp collisions at s = 8 $$ \sqrt{s}=8 $$ TeV. Phys. Rev. D 87: pp. 114015 Search for high-mass dilepton resonances in pp collisions at s = 8 $$ \sqrt{s}=8 $$ TeV with the ATLAS detector. Phys. Rev. D 90: pp. 052005 71. ATLAS collaboration, / Search for new phenomena in the dijet mass distribution using pp collision data at \( \sqrt{s}=8 \) / TeV with the ATLAS detector, 376" class="a-plus-plus">arXiv:1407.1376 [376" class="a-plus-plus">INSPIRE]. 72. Salvioni, E, Villadoro, G, Zwirner, F (2009) Minimal Z鈥?models: present bounds and early LHC reach. JHEP 11: pp. 068 CrossRef 73. Salvioni, E, Strumia, A, Villadoro, G, Zwirner, F (2010) Non-universal minimal Z鈥?models: present bounds and early LHC reach. JHEP 03: pp. 010 3(2010)010" target="_blank" title="It opens in new window">CrossRef 74. Barbieri, R, Pomarol, A, Rattazzi, R, Strumia, A (2004) Electroweak symmetry breaking after LEP-1 and LEP-2. Nucl. Phys. B 703: pp. 127 CrossRef 75. Cacciapaglia, G, Cs谩ki, C, Marandella, G, Strumia, A (2006) The minimal set of electroweak precision parameters. Phys. Rev. D 74: pp. 033011 Search for heavy neutrinos and W bosons with right-handed couplings in proton-proton collisions at s = 8 $$ \sqrt{s}=8 $$ TeV. Eur. Phys. J. C 74: pp. 3149 76. Cirigliano, V, Gonzalez-Alonso, M, Graesser, ML (2013) Non-standard charged current interactions: 尾 decays versus the LHC. JHEP 02: pp. 046 3)046" target="_blank" title="It opens in new window">CrossRef 77. Foot, R (1998) An alternative SU(4) 脳 SU(2)L 脳 SU(2)R model. Phys. Lett. B 420: pp. 333 370-2693(97)01519-0" target="_blank" title="It opens in new window">CrossRef 78. Volkas, RR (1996) Prospects for mass unification at low-energy scales. Phys. Rev. D 53: pp. 2681 79. Valencia, G, Willenbrock, S (1994) Quark-lepton unification and rare meson decays. Phys. Rev. D 50: pp. 6843 80. Carpentier, M, Davidson, S (2010) Constraints on two-lepton, two quark operators. Eur. Phys. J. C 70: pp. 1071 CrossRef 81. Bali, GS (2012) The strange and light quark contributions to the nucleon mass from Lattice QCD. Phys. Rev. D 85: pp. 054502
刊物类别:Physics and Astronomy
刊物主题:Physics Elementary Particles and Quantum Field Theory Quantum Field Theories, String Theory