Search for the neutrino magnetic moment in the nonequilibrium reactor-antineutrino energy spectrum

We study the time evolution of a typical reactor-antineutrino energy spectrum during the reactor operating period and the decay of the residual-antineutrino spectrum after the reactor is stopped. We find that relevant variations in the spectra of soft recoil electrons produced via weak and magnetic $\bar \nu _e e$ scattering can play a significant role in current and planned searches for the neutrino magnetic moment at reactors.     

CP violation and the search for new physics

Beta-delayed proton decay of ⁵⁷Zn has been investigated at the GSI on-line isotope separator. The studied ⁵⁷Zn nuclei were produced in fusion evaporation reactions by using a 150 MeV ³²S beam on a ²⁸Si target. Beta-delayed protons were measured by a charged-particle telescope detector. The observed decay pattern was used to construct the level scheme of ⁵⁷Cu and to extract the beta feeding distribution. The experimental results are compared with shell-model calculations. An erratum to this article is available at .     

Broad energy spectrum of laser-accelerated protons for spallation-related physics

A beam of MeV protons, accelerated by ultraintense laser-pulse interactions with a thin target foil, is used to investigate nuclear reactions of interest for spallation physics. The laser-generated proton beam is shown (protons were measured) to have a broad energy distribution, which closely resembles the expected energy spectrum of evaporative protons (below 50 MeV) produced in GeV-proton-induced spallation reactions. The protons are used to quantify the distribution of residual radioisotopes produced in a representative spallation target (Pb), and the results are compared with calculated predictions based on spectra modeled with nuclear Monte Carlo codes. Laser-plasma particle accelerators are shown to provide data relevant to the design and development of accelerator driven systems.     

Present and future experiments in nonequilibrium reactor antineutrino energy spectrum

Considerable efforts that have been undertaken in recent years in low-energy antineutrino experiments require further systematic investigations in line of reactor antineutrino spectroscopy as a metrological basis of these experiments. We consider some effects associated with the nonequilibrium of reactor radiation and residual emission from spent reactor fuel in contemporary experiments. The text was submitted by the authors in English.     

Model-independent search for new physics at D0 experiment

Finding the evidence of new physics beyond the Standard Model is one of the primary goals of RunII of the Tevatron. Many dedicated searches for new physics are ongoing at the Tevatron but in order to broaden the scope and maximize the chances of finding the new physics, we also search in a model-independent way. The results of such searches for indications of new physics at the electroweak scale are presented using data collected using the D0 detector from $p\bar{p}$ -interactions at $\sqrt {s} = 1.96$ ?TeV.     

A search for hidden variables in the domain of high energy physics

The idea of hidden variable theories, which contests the notion of quantum mechanics being the fundamental principle of nature, is well known and seems to need no introduction. In 1966 such a theory (of a non-local character) was proposed by D. Bohm and J. Bub. We present a scheme in which measured decay processes may constitute an adequate substitute to the original test proposed in 1966 and which until now proved to be realizable only for massless particles. Finally, we consider a specific proposal concerning Tau decays. A preliminary overview of several experimental data sets is presented.     

Tests of the standard model and search for new physics using flavor

The vast amount of flavor physics data available to date allows probing the presence of physics beyond the standard model through precision measurements of CP violating and CP conserving processes involving B, D, and K mesons. The information extracted from these measurements allows the characterization of physics beyond the standard model in a complementary way with respect to the direct searches at the Tevatron and the LHC. We review the status of the search for new physics with flavor-related observables. We discuss the status of the unitarity triangle analysis beyond the standard model: the inclusion of the recent measurements of B_s decays from the Tevatron experiments point to a discrepancy from the standard model expectation. In addition, we discuss the impact of O(Λ_QCD/m_b) corrections to the perturbative calculation of charmless hadronic B decays. These corrections can explain the puzzling values of direct CP asymmetries in B→Kπ decays within the standard model. These corrections cannot explain values of sin2β lower than the standard model value, as observed in b→s penguin decays. We conclude with the perspectives of the next generation of flavor-physics experiments, the precision they can reach and their phenomenological impact.     

Quasi-model-independent search for new high p(T) physics at D0

We apply a quasi-model-independent strategy ("Sleuth") to search for new high p(T) physics in approximately 100 pb(-1) of pp collisions at square root of (s) = 1.8 TeV collected by the D0 experiment during 1992-1996 at the Fermilab Tevatron. We systematically analyze many exclusive final states and demonstrate sensitivity to a variety of models predicting new phenomena at the electroweak scale. No evidence of new high p(T) physics is observed.     

The possibility of searching for new physics in cosmic rays

One possible explanation of cosmic-ray energy spectrum behavior around the knee (3–5 PeV) by means of production of new heavy particles or a new state of matter is considered. It is shown that, in this case, a large excess of muons and neutrinos with energies of >100 TeV must be generated. The existing VHE muon experimental data are analyzed. Possible experiments on VHE muon investigations are discussed.     

Particle accelerator physics and technology for high energy density physics research

Interaction phenomena of intense ion- and laser radiation with matter have a large range of application in different fields of science, extending from basic research of plasma properties to applications in energy science, especially in inertial fusion. The heavy ion synchrotron at GSI now routinely delivers intense uranium beams that deposit about 1 kJ/g of specific energy in solid matter, e.g. solid lead. Our simulations show that the new accelerator complex FAIR (Facility for Antiproton and Ion Research) at GSI as well as beams from the CERN large hadron collider (LHC) will vastly extend the accessible parameter range for high energy density states. A natural example of hot dense plasma is provided by our neighbouring star the sun, and allows a deep insight into the physics of fusion, the properties of matter at high energy density, and is moreover an excellent laboratory for astroparticle physics. As such the sun's interior plasma can even be used to probe the existence of novel particles and dark matter candidates. We present an overview on recent results and developments of dense plasma physics addressed with heavy ion and laser beams combined with accelerator- and nuclear physics technology.     

Understanding search trees via statistical physics

We study the randomm-ary search tree model (wherem stands for the number of branches of the search tree), an important problem for data storage in computer science, using a variety of statistical physics techniques that allow us to obtain exact asymptotic results. In particular, we show that the probability distributions of extreme observables associated with a random search tree such as the height and the balanced height of a tree have a travelling front structure. In addition, the variance of the number of nodes needed to store a data string of a given sizeN is shown to undergo a striking phase transition at a critical value of the branching ratiom _c = 26. We identified the mechanism of this phase transition and showed that it is generic and occurs in various other problems as well. New results are obtained when each element of the data string is a D-dimensional vector. We show that this problem also has a phase transition at a critical dimension,D _c = π/ sin^-1 (l/√8) = 8.69363 …     

深度学习在高能物理领域中的应用

深度学习是一类通过多层信息抽象来学习复杂数据内在表示关系的机器学习算法。近年来,深度学习算法在物体识别和定位、语音识别等人工智能领域,取得了飞跃性进展。文章将首先介绍深度学习算法的基本原理及其在高能物理计算中应用的主要动机。然后结合实例综述卷积神经网络、递归神经网络和对抗生成网络等深度学习算法模型的应用。最后,文章将介绍深度学习与现有高能物理计算环境结合的现状、问题及一些思考。     

Near-equilibrium measurements of nonequilibrium free energy

A central endeavor of thermodynamics is the measurement of free energy changes. Regrettably, although we can measure the free energy of a system in thermodynamic equilibrium, typically all we can say about the free energy of a nonequilibrium ensemble is that it is larger than that of the same system at equilibrium. Herein, we derive a formally exact expression for the probability distribution of a driven system, which involves path ensemble averages of the work over trajectories of the time-reversed system. From this we find a simple near-equilibrium approximation for the free energy in terms of an excess mean time-reversed work, which can be experimentally measured on real systems. With analysis and computer simulation, we demonstrate the accuracy of our approximations for several simple models.     

Improved sensitivity in the search for a parity-violating energy difference in the vibrational spectrum of the enantiomers of CHFClBr

The theoretical prediction that enantiomers of chiral molecules have different spectra because of parity violation associated with neutral currents in the weak interaction has been experimentally looked for. Last searches of a frequency difference in the vibrational spectrum of the enantiomers of CHFClBr obtained with our infrared saturation spectrometer is presented. The frequencies of a saturation resonance of separated enantiomers of CHFClBr have been compared at a 5×10^-14 level. A residual pressure shift probably induced by uncontrolled impurities of the samples has been observed and found to limit our experimental sensitivity. Finally no parity violating frequency difference is observed within the present sensitivity of 2.5×10^-13. A new experimental scheme is proposed which should let the parity violation effect observable. Received 22 January 2002 Published online 19 July 2002     

Wigner functions in high energy physics

Recent developments are (meta)reviewed in the applications of Wigner functions to describe the observed single-particle spectra and two-particle Bose-Einstein (or Hanbury Brown-Twiss) correlations in high energy particle and nuclear physics, with examples from hadron-proton and Pb+Pb collisions at CERN SPS.     

Recent developments in high energy physics

Recent results from experiments with solar, atmospheric and accelerator neutrinos are presented. Some of the important results from the LEP and TEVATRON colliders are summarised.