Upcoming Particle Seminars*

September 19

Speaker: Markus Klute, Massachusetts Institute of Technology

Title: "Observation of a new boson with mass near 125 GeV with CMS"

Abstract: 

On July 4, 2012, the discovery of a new boson, with mass around 125 GeV and with properties compatible with those of a standard-model Higgs boson, was announced at CERN. I will present the results of the search with the CMS detector. The search is performed in five decay modes: gg, ZZ, WW, tau tau and bb. An excess of events is observed above the expected background, with a local significance of 5.0 standard deviations signaling the production of a new particle.

October 3

Speaker: Matthew Moulson

Title: "The NA62 experiment: Rare kaon decays at the CERN SPS"

Abstract: 

The flavor-changing neutral-current decays K → π νν¯ are highly sup-pressed in the Standard Model, while their rates can be predicted with minimal theoretical uncertainty. The branching ratios for these decays are therefore sensitive probes of the flavor sector of the Standard Model, providing constraints on the CKM unitarity triangle that are complementary to those from measurements of B-meson decays. However, the tiny branching ratios and challenging experimental signatures for these decays make them notoriously difficult to measure. The goal of NA62, an experiment at the CERN SPS, is to detect ∼ 100K+ → π+νν¯ decays with an S/B ratio of10:1 in two years of data taking starting in 2014. The experiment will make use of the NA48 calorimeter and beamline and a host of new detectors, which are now under construction. In 2007 and 2008, the new collaboration took data with the NA48 detector to measure RK , the ratio of rates for K → µν to K → µν, the value of which could potentially reveal evidence for super-symmetry. After a brief discussion of NA62’s measurement of RK , I will describe the physics of the K → πνν¯ decays and the NA62 measurement strategy and physics program.

October 17

Speaker: Marlene Doert, Technical University of Dortmund

Title:  "Deconvolution of data - solving inverse problems in (astro-) particle physics"

Abstract: 

Inverse problems appear in any kind of indirect measurement process, be it the task of understanding a particle collision event by tracking its secondary particles, or to determine the energy of a cosmic event by measuring the light produced in the atmosphere by the resulting particle cascade. I will discuss these so-called "ill-posed" problems and present a statistical analysis technique which is commonly used to solve them: the method of unfolding or deconvolution of data. Besides the generic approach and the inherent difficulties such as oscillating solutions and the need for regularization methods, I will present the novel unfolding program TRUEE, which has been implemented by the astroparticle physics group at TU Dortmund. TRUEE offers a numerical, event-based solution of inverse analysis problems and makes use of the Tikhonov regularization method. I will illustrate the functionality of the program by presenting analysis examples from the MAGIC gamma-ray telescopes and the IceCube neutrino detector.

October 24

Speaker: Kazuhiro Terao, Massachusetts Institute of Technology

Title: "Searching for Ѳ13 Using Neutron Capture on Hydrogen in Double Chooz"

Abstract: 

Double Chooz is a reactor antineutrino experiment built to measure Ѳ 13. The experiment uses two detectors at different baselines (400 m and 1 km) to precisely measure the disappearance of ῡₑ from the Chooz reactor cores in Ardenne, France. Our inverse beta decay (IBD) signal is a two-fold coincidence of a prompt positron followed by a delayed neutron capture on Gadolinium (Gd). The delayed neutron capture releases 8 MeV of energy from multiple gamma rays and is easily distinguished from natural radioactive backgrounds. While delayed neutron capture on Gd is used in all the reactor-based Ѳ 13 measurements, it is also possible to detect IBD via delayed neutron capture on Hydrogen. In Double Chooz the Hydrogen detection channel has twice the signal statistics as the Gd detection channel and provides an independent data sample with which to cross-check the Gd analysis result. Furthermore, because of the very different nature of the backgrounds and systematic uncertainties, a combination of the Hydrogen and Gd analysis may help us better constrain the value of Ѳ 13. In this seminar, I present the current status and preliminary results from the Hydrogen analysis in Double Chooz.

December 10 - MONDAY

Speaker: Michael Sutherland, Louisiana State University

Title: "Ultra-High Energy Cosmic Rays and The Pierre Auger Observatory"

Abstract: 

Ultra-high energy cosmic rays are the most energetic particles in the universe but their properties are poorly understood. While most are charged, their actual composition is unknown. There also is little knowledge of their extragalactic sources due to deflection of their trajectories in intervening magnetic fields. The extremely low flux of these particles, less than 1 particle km ${^-2}$ yr$^{-1}$ above $10^{18}$ eV, necessitates indirect detection methods using the extensive air showers initiated when the cosmic ray primary interacts with air molecules within the atmosphere. Located in the high pampa of Argentina, the Pierre Auger Observatory is the largest cosmic ray detector in the world and combines two traditional air shower detection techniques: air fluorescence telescopes and water Cherenkov ground-based detectors. These allow precision measurements of the energy spectrum and the arrival directions, as well as data to infer the chemical composition of the cosmic ray primaries. I will discuss recent results from the Observatory as well as my contributions on magnetic corrections for source identification.

December 17 - MONDAY

Speaker: Jonathan Eisch, University of Wisconsin

Title: "Measurement of the spectrum and composition of cosmic rays with IceTop and IceCube"

Abstract: 

The IceCube Neutrino Observatory and its associated surface array, IceTop, form a fully-integrated three-dimensional cosmic ray detector.  IceTop, located on the surface of the South Polar ice sheet at 3000 m above sea level, is sensitive to the electromagnetic component of cosmic ray air showers, while IceCube, buried 1400 m below the surface, is sensitive to deeply penetrating high-energy muons.  By combining information from the two detectors, it is possible to reconstruct both the energy and mass of primary cosmic rays.  In combination, the detectors are sensitive to cosmic rays with energies between 1 and 100 PeV, a transition region in the cosmic ray spectrum known as the "knee."  In this talk I will present an unfolding technique used to determine the average energy-dependent mass composition of cosmic rays in this energy range.  The measurement of cosmic ray composition may shed light on the origin of cosmic rays in the knee region.