76 research outputs found

    Towards establishing the spin of warped gravitons

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    We study the possibility of experimental verification of the spin=2 nature of the Kaluza-Klein (KK) graviton which is predicted to exist in the extra-dimensional Randal-Sundrum (RS) warped models. The couplings of these gravitons to the particles located on or near the TeV brane is the strongest as the overlap integral of their profiles in the extra-dimension is large. Among them are unphysical Higgses (WLΒ±W^{\pm}_L and ZLZ_L) and KK excitations of the Standard Model (SM) gauge bosons. We consider the possibility to confirm the spin-2 nature of the first KK mode of the warped graviton (G1G_1) based on the angular distribution of the Z bozon in the graviton rest frame in the ggβ†’G1β†’WKK(ZKK)W(Z)β†’WWZ\to G_1 \to W^{KK} (Z^{KK}) W (Z)\to WWZ, ggβ†’G1β†’ZZ\to G_1\to ZZ and ggβ†’G1β†’ZKKZβ†’ZZH\to G_1 \to Z^{KK} Z\to ZZH decay channels. Using Wigner D-matrix properties, we derive the relationship between the graviton spin, signal angular distribution peak value, and other theoretically calculable quantities. We then study the LHC signals for these decay modes and find that with 1000 fbβˆ’1^{-1} of data, spin of the RS graviton up to ∼\sim 2 TeV may be confirmed in the ppβ†’WKK(ZKK)W(Z)β†’WWZβ†’pp \to W^{KK} (Z^{KK}) W (Z) \to WWZ \to 3 leptons + jet + \slashed{E}_T and ppβ†’ZZβ†’pp \to ZZ \to 4 leptons decay modes.Comment: 19 pages, 6 figure

    The Mirage of the Fermi Scale

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    The discovery of a light Higgs boson at LHC may be suggesting that we need to revise our model building paradigms to understand the origin of the weak scale. We explore the possibility that the Fermi scale is not fundamental but rather a derived one, i.e. a low energy mirage. We show that this scenario emerges in a very natural way in models previously used to break the electroweak symmetry dynamically and suggest a simple dynamical framework for this idea. In our model the electroweak scale results from the interplay between two very high energy scales, one typically of the order of \Luv\sim 10^{10} GeV and the other around MU∼1016M_{\rm U} \sim 10^{16} GeV, although other values are also possible.Comment: 5 pages, 1 figur

    Applications of effective field theories within and beyond the Standard Model

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    We review the role of the effective field theories in modern physics, especially modern elementary particle physics. We provide field-theoretical description of the three effective field theories: chiral perturbation theory, heavy-quark effective theory and Randall-Sundrum (RS) Model. Applications of these formalisms in the particle physics research are discussed, ranging from B-physics and baryon physics to search for the first RS Kaluza-Klein graviton mode via gluon-fusion process at the LHC

    Conformal Extensions of the Standard Model with Veltman Conditions

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    Using the renormalisation group framework we classify different extensions of the standard model according to their degree of naturality. A new relevant class of perturbative models involving elementary scalars is the one in which the theory simultaneously satisfies the Veltman conditions and is conformal at the classical level. We term these extensions perturbative natural conformal (PNC) theories. We show that PNC models are very constrained and thus highly predictive. Among the several PNC examples that we exhibit, we discover a remarkably simple PNC extension of the standard model in which the Higgs is predicted to have the experimental value of the mass equal to 126 GeV. This model also predicts the existence of one more standard model singlet scalar boson with a mass of 541 GeV and the Higgs self-coupling to emerge radiatively. We study several other PNC examples that generally predict a somewhat smaller mass of the Higgs to the perturbative order we have investigated them. Our results can be a useful guide when building extensions of the standard model featuring fundamental scalars.Comment: 18 pages, updated to match published versio

    A natural Coleman-Weinberg theory explains the diphoton excess

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    It is possible to delay the hierarchy problem, by replacing the standard Higgs-sector by the Coleman-Weinberg mechanism, and at the same time ensure perturbative naturalness through the so-called Veltman conditions. As we showed in a previous study, minimal models of this type require the introduction of an extra singlet scalar further coupled to new fermions. In this constrained setup the Higgs mass was close to the observed value and the new scalar mass was below a TeV scale. Here we first extend the previous analysis by taking into account the important difference between running mass and pole mass of the scalar states. We then investigate whether these theories can account for the 750 GeV excess in diphotons observed by the LHC collaborations. New QCD-colored fermions in the TeV mass range coupled to the new scalar state are needed to describe the excess. We further show, by explicit computation of the running of the couplings, that the model is under perturbative control till just above the masses of the heaviest states of the theory. We further suggest related testable signatures and thereby show that the LHC experiments can test these models.Comment: Discussion on the perturbative limits of the model is added, Fig.1 updated and new Fig.2 is added; References update
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