Bulletin of the American Physical Society
2008 APS April Meeting and HEDP/HEDLA Meeting
Volume 53, Number 5
Friday–Tuesday, April 11–15, 2008; St. Louis, Missouri
Session H12: New Ideas |
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Sponsoring Units: DPF Chair: Cecilia Gerber, University of Illinois at Chicago Room: Hyatt Regency St. Louis Riverfront (formerly Adam's Mark Hotel), St. Louis C |
Sunday, April 13, 2008 8:30AM - 8:42AM |
H12.00001: Vector Currents of Massive Neutrinos of an Electroweak Nature Rasulkhozha Sharafiddinov The mass of an electroweakly interacting neutrino consists of the electric and weak parts responsible for the existence in it of charge, charge radius and magnetic moment. Such connections explain the formation of paraneutrinos, for example, at the polarized neutrino electroweak scattering by spinless nuclei. We derive the structural equations which relate the mass and its self components to charge, charge radius and magnetic moment of each neutrino as a consequence of unification of fermions of a definite flavor. Findings open the possibility for establishing the laboratory limits of weak masses of all Dirac types of neutrinos. Thereby, they show that the earlier measured properties of these particles may serve as a certain confirmation of the availability of mass structure of their interaction with field of emission. [Preview Abstract] |
Sunday, April 13, 2008 8:42AM - 8:54AM |
H12.00002: Heavy Lepton Production with Anomalous Interactions Ahmet Tolga Tasci, Ahmet Turan Alan We consider possible production of heavy leptons via anomalous interactions at future $ep$ colliders (THERA and LHeC), $e^+e^-$ colliders (ILC and CLIC) and $pp$ collider CERN LHC. From the signal and background analysis of heavy leptons we obtained upper mass limits of 650 GeV at LHeC, 450 GeV at ILC and 600 GeV at LHC with optimal choices of relevant parameters. [Preview Abstract] |
Sunday, April 13, 2008 8:54AM - 9:06AM |
H12.00003: An Isothermal and Isochromatic Comparison of Gall's and Planck's Black Body Radiation Laws Clarence A. Gall Gall's black body radiation law $\left( I_{\lambda } =\sigma \frac{T^{6}}{b^{2}}\lambda e^{-\frac{\lambda T}{b}} \right )$ derived by treating emission as a decay process (BAPS, March 2007, X21.4, Denver, CO), exactly satisfies the three empirical laws of black body radiation and employs the same empirical constants. Planck's law $\left( I_ {\lambda }=\frac{c_{1}}{\lambda ^{5}}\frac{1}{e^{\frac{c_{2}} {\lambda T}}~~-1}\right )$ is seen as a modification of Wien's law $\left( I_{\lambda }=\frac{c_{1}}{\lambda ^{5}} \frac{1}{e^{\frac{c_{2}}{\lambda T}}}\right )$ with new parameters derived from the idea that EMR travels in packets (quanta). Planck's law allows for further adjustments of the constants than does Wien's law, so as to better fit the empirical laws, but these constants are not identical to the empirical constants. The exponent in $\lambda ^{-5}$ also has to be adjusted for a better intensity fit. While the isothermal curves for the laws of Gall and Planck both show a maximum intensity defined by Wien's displacement law $\left( \lambda _{m}T=b\right)$, the isochromatic curves are markedly different. Gall's law gives a maximum at $\lambda T_ {m}=6b$ whereas Planck's law shows a continuous increase of intensity with temperature. The latter thus appears to lead to a high temperature catastrophe. Measurement of the isochromatic curves should provide a definitive test of the validity of these laws. [Preview Abstract] |
Sunday, April 13, 2008 9:06AM - 9:18AM |
H12.00004: Bifurcations and pattern formation in particle physics: a model study Ervin Goldfain Quantum field theories, regardless of their formal content, lead to a large number of coupled nonlinear field equations. In general, solving these equations in closed form or through lattice-based computations has been accomplished with modest or limited success. Our study suggests that the theory of nonlinear dynamical systems offers a fresh approach to this challenge. Working from the universal route to chaos in coupled systems of differential equations, we find that: a) particles acquire mass as plane wave solutions of the complex Landau-Ginzburg equation (CLGE), without any reference to the hypothetical Higgs scalar; b) the $U(1)\times SU(2)$ and $SU(3)$ gauge groups, as well as leptons and quarks, become progressively generated through bifurcations of CLGE. [Preview Abstract] |
Sunday, April 13, 2008 9:18AM - 9:30AM |
H12.00005: Fractional dynamics as source of CP violation in the Standard Model Ervin Goldfain The origin of CP violation in K-meson channels and the strong CP problem are long-standing puzzles of the Standard Model. Building on our recent contributions$^{1), 2)}$ we find that breaking of CP symmetry is a direct manifestation of fractional dynamics and non-equilibrium phenomena in particle physics. Our results are summarized below: \[ \left| \varepsilon_K \right|_{EXP} =(2.280\pm 0.013)\times 10^{-3}, \quad \left| \varepsilon_K \right|_{THEOR} =2.162\times 10^{-3} \] \[ \left| {\varepsilon_K}^{'} \right|_{EXP} =(3.878\pm 0.16)\times 10^{-6}, \quad \left| {\varepsilon_K}^{'} \right|_{THEOR} =4.670\times 10^{-6} \] \[ (\theta _{QCD} )_{EXP} <10^{-10}, \quad (\theta _{QCD} )_{THEOR} <3.491\times 10^{-10} \] Here, $\left| \varepsilon_K \right|$, $\left| {\varepsilon_K}^{'} \right|$ are the two CP parameters describing the K-meson sector and $\theta _{QCD} $ the CP term associated with the vacuum structure of Quantum Chromodynamics. 1) E. Goldfain, Communications in Nonlinear Science and Numerical Simulation,~Volume 13, Issue 3,~June 2008, Pages 666-676 2) E. Goldfain, Communications in Nonlinear Science and Numerical Simulation,~Volume 13, Issue 7,~September 2008, Pages 1397-1404 [Preview Abstract] |
Sunday, April 13, 2008 9:30AM - 9:42AM |
H12.00006: The embodiment of the e-Science for High Energy Physics Hyunwoo Kim, Kihyeon Cho The e-Science for High Energy Physics is to study High Energy Physics (HEP) any time and anywhere even if we are not on-site of accelerator laboratories. The contents are 1) data production, 2) data processing and 3) data publication any time and anywhere. The data production is to do remote control and take shifts remotely. The data processing is to run jobs anytime, anywhere using Grid farms. The data publication is to work together to publish papers using collaborative environment such as EVO (Enabling Virtual Organization) system. We apply this concept to high energy physics experiments using LCG farm at KISTI (Korea Institute of Science and Technology Information) and show the results. [Preview Abstract] |
Sunday, April 13, 2008 9:42AM - 9:54AM |
H12.00007: Nature of Reality Sunil Thakur In this paper, I have examined entire spectrum of the issues concerning reality. We need to make two fundamental changes in our understanding of how nature manages universe. We must give up the idea that FTL communication is not possible. Second major change is that an object remains unmanifested till it finds a medium through which it can manifest itself. How the reality is revealed does not depend only on the properties of the reality itself but also depends on the properties of the medium through which the object is manifested. Light and heat are manifested information and therefore cannot carry information. Nothing exists that has illumination as its inherent property; photon is energy particle (not light particle). Matter is manifested energy; matter does not distort space, matter is distorted space. Light and heat remain unmanifested till energy finds matter to manifest itself. Light does not travel; each particle illuminates as it receives energy from previous particle and acts as a `light bulb' and hence illusion of forward motion. All communication in the universe takes place through radiation and radiation emitted by the object is directly proportionate to the energy incident upon it. Two experiments provide experimental evidence to this theory. [Preview Abstract] |
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