PHY599: Graduate Seminar II: (Nuclear, Particle, Astronomy)

Fall 2006

Place and Time:

Course Web Page:

Instructors:

Prof. Barbara Jacak

Office: Physics C-102, Phone: 632-6041

Prof. Michael Marx

Office: E3320 Melville Library (College of Arts & Sciences), Phone: 632-6968

Prof. Michael Zingale

Office: ESS 440, Phone: 632-8225,

Meeting Schedule:

date	first speaker	second speaker
Sept. 6	organizational meeting
Sept. 13	no meeting
Sept. 20	no meeting
Sept. 27	Benedikt Scharfenberger Atmospheric Neutrinos and Neutrino Oscillations	Ilmo Sung Search for the Higgs Boson
Oct. 4	Regina Caputo CP Violation in K Decay	Julia Novak Search for Supersymmetric Particles
Oct. 11	Marco Springmann Large Extra Dimensions and Grand Unification at the Electroweak Scale	Stephen Webb Color Superconductivity and QCD at High Density
Oct. 18	Xiaoxu Lu J/Psi suppression, a signature for deconfinement of quarks	Li Li Measurements of the Electron Neutrino Mass
Oct. 25	Tobias Strehlau Type Ia Supernovae Explosion Models	Mohammad Rahman Detection of Neutrinos from the Sun
Nov. 1	Jason Farley Where Are the Quarks Inside Nuclei?	Jiayin Sun Ultra High Energy Cosmic Ray Events
Nov. 8	Zhengwen Zhang Quantum Chromo-Dynamics	Abhijit Gadde Search for Proton Decay
Nov. 15	Stephen Webb QCD Phase Diagrams
more meetings will be scheduled depending on enrollment

Objectives:

• Obtain experience in giving oral presentations.
• Learn some of what is happening in these fields.
• Learn about research activities at Stony Brook.
• Attend colloquia and learn about presentation/clarity.

Topics:

• Nuclear Physics
• Particle Physics
• Astronomy

For electronic article access, try the university license to APS Journals (Physical Review) or the electronic preprint archive at Los Alamos); for searching published work in astronomy, the ADS abstract service is excellent. For particle physics, the web sites of large experiments can be helpful in finding publications.

Rules:

• Each student will give one 30 minute talk, with 5-10 additional minutes to allow for questions and discussion during and after the talk.
  • Make sure to stay close to the allotted time, but don't exceed the time limit. Be aware that if you speak for significantly longer than the alloted time, you may be interrupted and not be allowed to finish your presentation. This is a constraint that is consistent with the practices at many conferences.
  • Make sure you have a goal with the presentation: present the essential (new) physics, provide connections (previous data/theory), present the underlying concepts, and give a compact summary.
  • Your fellow students must be able to learn something (new) from your presentation: make sure you start at a general level of knowledge.
  • Avoid long and complex derivations; provide the essence or the outline of derivations if needed
  • You are responsible for researching the literature and contacting the local experts.
  • Instructors or experts may be consulted on the organization, layout, and content of your presentation at any time, but you will be solely responsible for the final product. Materials used in presentations should be drawn mostly from published materials (journal papers, preprints, etc.). Photos, figures, plots and other information can be obtained from web pages. However, students are strongly discouraged from directly using other people's transparencies, including those from an expert adviser.
  • Students are strongly encouraged to arrange a practice talk in front of fellow students a few days preceding their presentation. Practice the correct presentation: attitude, position, volume, speed, and timing!
  • See the list of suggestions for hints to help prepare slides for a good presentation.
  • You are encouraged to provide an electronic version of the talk in PDF to be posted on the web page.
• Scheduled talks may not be postponed.
• Students must meet with an instructor and turn in an electronic abstract at least one week preceding the talk.
  • Prepare a APS formatted abstract with the proper references (See the LATEX source, w/ apsab.sty)
• Students must attend all talks; attendance will be taken.
• Students are encouraged to ask questions and give criticisms of talks. Active participation will be part of the grade.

Grade:

• Physics content of presentation: 50%
• Presentation quality of the talk: 30%
• Quality of the Abstract: 10%
• Active participation in class discussion 10%
• Attendance will be taken. Unexcused absences will result in a lower grade

Special Notes:

Any excuses (medical or otherwise) are to be documented, and discussed with the instructors in a timely manner. If you have a physical, psychological, medical or learning disability that may impact on your ability to carry out assigned course work, we urge that you contact the staff in the Disabled Student Services office (DSS), Room 133 Humanities, 632-6748/TDD. DSS will review your concerns and determine, with you, what accommodations are necessary and appropriate. All information and documentation of disability is confidential.

Topics in Nuclear Physics

The Phase-Diagram of Nuclear Matter:

The QCD phase diagram exhibits a large number of different phases including normal nuclear matter, dense hadron matter, quark gluon plasma, color super conductors. Discuss the phase diagram and its characteristic features and their theoretical basis. Explain which parts can be addressed by which experimental techniques. (Drees, Shuryak, Hemmik)

Quenching of Jets and Heavy Quark Energy Loss:

Jets of particles in the final state of a collision arise from quarks or gluons scattering with large momentum transfer. In heavy ion collisions the quarks or gluons lose a large amount of energy in the dense medium as they traverse it. Even the very heavy charm quarks experience huge energy losses, which is quite surprising. Discuss the results, focusing on either theoretical or experimental aspects. (Drees, Jacak)

J/Psi suppression, a signature for deconfinement of quarks:

In collisions of heavy ions fewer J/psi mesons are produced than expected from summing independent nucleon-nucleon collisions. This was predicted as a signature of quark-gluon plasma formation. Briefly describe the concept of quark gluon plasma. Discuss the mechanism of suppression of the J/psi and recent data. (Drees, Jacak)

Electromagnetic Radiation from Hot, Dense Nuclear Matter:

Enhanced radiation of lepton pairs from the hot and dense reaction volume created in collision of nuclei was discovered at CERN and is beginning to be probed at RHIC. The data indicate melting of the QCD vacuum and therefore the presence of a QCD phase transition. Show the experimental results and interpretations. (Hemmick, Drees, Zahed)

Statistical Mechanics of Nuclear Collisions:

The number and spectra of particles produced in heavy ion collisions is well described by statistical emission from an equilibrated gas of hadrons. Data indicate that hadrons decouple at a temperature near 170 MeV, near the QCD phase transition between quarks and hadrons. Describe the measurements, statistical analysis and interpretation. (Shuryak, Jacak, Hemmick)

Particle Interferometry:

The space-time extent of the collision region formed in nuclear reactions can be studied by measuring the interference between two identical outgoing particles. Measurements at RHIC show a surprise: the sizes are no larger than at lower energy, even though RHIC produces more particles and more explosive collisions. Explain the technique and discuss the recent results. (Jacak, Hemmick, Brown, Shuryak)

Elliptic Flow of Matter

The high particle multiplicity in heavy ion collisions produces high pressure and non-isotropic particle emission patterns. The anisotropy at RHIC is large and indicates rapid equilibration and very low viscosity followed by hydrodynamic expansion. Discuss the phenomenon and to what extent it indicates quark gluon plasma formation. (Shuryak, Hemmick)

Where are the quarks inside nuclei?

Discuss scattering of leptons from nuclei and dilepton production via the Drell-Yan process to probe quark and antiquark distributions. What do we learn from such data about the quark structure functions, and what is the effect of the nuclear medium? (Jacak, Marx)

Where is the spin of the proton?

Results from deep inelastic scattering experiments using polarized electrons and polarized protons indicate that the quark spin contribution to the spin of the proton is essentially zero. Review these experiments and discuss upcoming attempts at Brookhaven to measure the polarization of gluons inside the proton. (Deshpande, Jacak, Shuryak)

Measurements of the Electron Neutrino Mass:

Discuss the various experiments to measure electron neutrino masses from beta-decay endpoint measurements and double-beta decay. Give the latest results and discuss the relation of these results to the recent observations of neutrino oscillations. (Shrock, Jung)

Parity Non-conservation in Atoms:

The strength of parity violating transitions in atoms allow determination of standard-model parameters at low q-squared. Discuss the experiments and the model sensitivities. (Sprouse)

Nuclear Sizes and Moments from Hyperfine Laser Spectroscopy:

Precise data on nuclear charge radii and electromagnetic moments can be obtained from hyperfine spectroscopy using lasers. Discuss how these experiments are done. Give examples of deduced nuclear properties such as the nuclear compressibility. Also discuss the use of laser spectroscopy to trap radioactive ions to study parity non-conservation in atomic transitions. (Sprouse)

Super-Heavy Nuclei:

Well-founded nuclear model calculations have predicted a stable (lifetimes between 1 and 100 years) island of very heavy nuclei near Z--114 and A--300. A few such nuclei have recently been detected. Discuss the theoretical basis for the super-heavy island and the possible approaches to it by use of heavy ion reactions. Discuss the (somewhat controversial) results from recent experiments. (Sprouse, Jacak)

Nuclear Liquid-Gas Phase Transition:

Under the influence of heat and pressure nuclear matter is expected to undergo a liquid-gas phase transition. This is the boiling point of nuclear matter. Report on recent experiment showing fragmentation of nuclei into large clusters (droplets) at intermediate energies (several 100 MeV/u) which are interpreted in terms of such a phase transition. Discuss the theoretical connection of these experiments with a phase transition from a nuclear liquid to a nuclear gas phase. (Jacak)

Color Superconductivity and QCD at High Density:

Quark matter at high density is believed to display a number of interesting phases, with quark Cooper pairs condensing like in an ordinary superconductor. Those pairs are diquarks which are already observed inside the ordinary nucleons. (Zahed,Shuryak)

The Perfect Fluid Created at RHIC:

The hot, dense matter formed at RHIC has shown surprising properties. It is extremely opaque to colored probes (quarks and gluons) traversing it. The matter thermalizes incredibly quickly and behaves like a liquid with extremely small viscosity. Screening of the color charges does not appear to be complete. Similar properties are observed in strongly coupled plasmas, and are being studied using the correspondence of string theory and quantum field theory. Discuss either the experimental evidence for strongly coupled plasma formation or theoretical studies of its properties utilizing AdS/CFT correspondence. (Zahed, Shuryak, Jacak)

Topics in Elementary Particle Physics

Discovery of the Top Quark:

Discuss the discovery and the measurements of top quark production cross section and the top quark mass by the DØ and CDF experiments. Discuss the signatures and methods used, and the significance of the precise measurement of the top quark mass for the prediction of the Higgs boson mass. (McCarthy, Hobbs)

Search for the Higgs Boson:

Discuss the search for the Standard Model Higgs boson carried out at LEP, at the upgraded TeVatron, and at the Large Hadron Collider. What are the different strategies as function of the mass and the prospects for success? (Hobbs, Rijssenbeek)

Precision Measurement of the Z Boson Parameters:

Measurements at the SLAC SLC collider and the CERN LEP collider of the Z boson mass, width, and production cross section. Relevance to tests of the Standard Model. (Hobbs, Rijssenbeek, Gonzalez-Garcia)

Quantum Chromo-Dynamics:

Discuss the gauge theory of QCD. Discuss recent results on high energy jet production in the framework of perturbative QCD calculations and experimental measurement techniques by the DØ and CDF collaborations. (McCarthy, Sterman)

Large Extra dimensions and Grand Unification at the Electroweak Scale:

Discuss the recent theoretical developments in trying to obtain Grand Unification of the elementary forces in the neighborhood of the electroweak scale (1 TeV) by postulating the existence of "large" (µm to mm) extra dimensions. Review existing and ongoing experimental research in gravity at the sub-millimeter scale, and predictions for physics at the Tevatron and the large hadron collider LHC at CERN. (Van Nieuwenhuizen, Hobbs, Rijssenbeek)

Parton Structure of the Proton:

How do we measure the quark and gluon distributions in the proton? How do they vary with q-squared? What is the spin content of the proton? (Smith, McCarthy)

Precision Measurement of the W Boson Mass:

Discuss the precision measurement of the W mass at the FNAL TeVatron collider by the DØ and CDF collaborations and by the four LEP collaborations. Discuss the measurement methods and the achieved precision. Explain its importance as a test of the Standard Model, as well as the ultimate test of one's understanding of the detector.. (Rijssenbeek, McCarthy)

Detection of Neutrinos from the Sun:

Discuss the major ongoing experiments (Super-Kamiokande, SNO, Davis, Gallex/GNO, Sage) that measure the flux of solar neutrinos. Give their latest results and the implications of these results on standard solar models and the Standard Electroweak model. Summarize the concrete plans for new experiments. (Jung, McGrew, Yanagisawa, Gonzalez-Garcia)

Detection of Neutrinos from Supernovae:

Neutrinos from the supernova SN1987a are the only astrophysical neutrinos observed other than solar neutrinos. Discuss the supernova neutrino production mechanism, observation of neutrinos from SN1987a, experimental observation methods and future prospects. (Jung, Yanagisawa, Lattimer)

Atmospheric Neutrinos and Neutrino Oscillations:

Discuss the origin of atmospheric neutrinos and the expected fluxes of electron-type and muon-type neutrinos. Discuss the experimental measurements that differ from the predicted values and possible explanations for the discrepancy. And finally discuss the recent Super-Kamiokande results that show evidence for neutrino oscillations, and supporting evidences from other experiments. (Jung, McGrew, Yanagisawa,Gonzalez-Garcia)

Long Baseline Neutrino Oscillation Experiments and Lepton Mixing Matrix:

Observations of neutrino oscillations by the underground experiments in the atmospheric and solar neutrinos have revolutionized the particle physics. There are efforts to further confirm this findings using accelerator produced neutrino beams and to measure the lepton mixing matrix elements, which doesn't exist in the Standard Model. Give the latest results from the K2K experiment and summarize the plans for new experiments (MINOS, CNGS and JHFnu). (Jung, McGrew, Yanagisawa, Shrock, Gonzalez-Garcia)

The Nature and Magnitude of the Neutrino Mass:

The neutrino oscillation signal observed by several experiments implies that neutrinos have a small, but finite mass. Discuss the implication of neutrino mass for the standard model of particle physics and what is known about the mass from neutrino oscillation experiments, direct mass searches,and neutrinoless double beta-decay experiments. Describe the experimental techniques use in either a direct mass, or a double beta-decay search.(McGrew,Gonzalez-Garcia,Shrock)

Ultra High Energy Cosmic Ray Events:

Two ground based experiments: AGASA and HiRES have claimed to observe cosmic ray events beyond so called "GZK cut-off". These events are the highest known particle interaction events (~10²⁰ eV). Explain the GZK cut-off. Give the latest results from these experiments and explore possible scenarios/explanations for these extraordinary events. Summarize the plans for new experiments. (Jung, McGrew, Yanagisawa, Gonzalez-Garcia, Marx)

Search for Proton Decay:

Discuss why many GUT theories require proton decay. Give an overview of the experimental situation, and present the current results and limits. (Jung, McGrew, Yanagisawa, Shrock)

Search for Supersymmetric Particles:

Discuss the basic concepts of supersymmetry, and search techniques. Present recent results and future prospects for the discovery of supersymmetry. (Hobbs, Jung, van Nieuwenhuizen, Shrock)

CP Violation in K Decay:

Review the evidence for CP violation and outline the phenomenology of the K0-anti-K0 system. Discuss recent measurements of CP violation and the prospect for further progress. (McCarthy, Shrock)

Mixing and CP Violation in the B-Bbar System:

Description of the theoretical basis and experimental techniques, including recent results and future prospects with the Fermilab TeVatron Collider detectors and B-factories. (Hobbs, Rijssenbeek, Smith)

g-2 Experiment:

Review the current status of the BNL g-2 experiment and its interpretation as indirect evidence for SUSY production. Why is this important? (McCarthy, Rijssenbeek, Shrock)

Topics in Astronomy

Supermassive Nuclear Black Holes:

Discuss evidence for their existence in both active and quiescent galaxies. (Evans)

High-redshift Galaxies:

The formation and early evolution of galaxies. (Lanzetta)

Big-Bang Nucleosynthesis:

Describe the present understanding of nucleosynthesis and discuss resulting constraints on particle physics and cosmology. (Lanzetta)

Quasar Absorption Lines:

What do they tell us about intervening galaxies and gas. (Lanzetta)

Type II Supernovae:

Discuss the process of explosive star death in detail. Or, discuss the observational and theoretical understanding of how the ejecta interact with the interstellar medium, and produce what we see as supernova remnants. (Lattimer, Brown)

Neutron (Quark?) Stars:

Discuss the structure, "birth", and evolution of neutron stars. Discuss recent measurements of the radius of an isolated nearby neutron star. (Lattimer, Walter, Brown)

Ultra-luminous Infrared Galaxies:

Ultra-luminous infrared galaxies have total luminosities that rival those of quasars. Discuss what they are and how they were detected. (Evans)

Dark Matter in Galaxies:

Discuss the discovery of invisible ("dark") matter in our and other galaxies. Discuss its proposed distribution and form, and the various proposed types of dark matter. What are its cosmological implications? (Lanzetta)

Microwave Background, its Fluctuations and Dark Energy:

Discuss the discovery of the cosmic microwave background. Focus on recent measurements of the fluctuations of the microwave background. Include recent balloon experiment results. What are the cosmological implications of these results? (Lanzetta)

Gamma-ray Bursts:

Discuss the basic properties of gamma-ray bursts and the post-1997 developments in our understanding of these cosmic fireworks. (Brown, Lattimer)

Extrasolar Planets:

Discuss the techniques used to find planets around other stars, the results of searches to date, and the implications for our understanding of solar-system formation. (Peterson)

Gravity Waves:

Discuss the theoretical relevance of gravity waves, the likely astrophysical sources of gravity waves, and past and future progress towards detecting them. (Lattimer)

Type Ia Supernovae and the Accelerating Universe:

Give a critical assessment of recent evidence from supernova studies that the cosmological constant is non-zero, and discuss the implications of a non-zero cosmological constant. (Lanzetta)

Type Ia Supernovae Explosion Models:

Describe the theoretical picture of a Type Ia supernova explosion. Discuss the current outstanding questions. (Zingale)

Type I X-ray Bursts:

Explain the physics of Type I X-ray bursts, summarizing the observational properties and the theoretical model. Explain their importance in determining the properties of the underlying neutron star. (Zingale)

Star and Planet Formation:

Describe what we know about the process. In particular, discuss what chondrules tell us about the conditions in the early solar system. (Walter)

Solar flares:

What new light do the recent TRACE images/movies throw on the interaction between magnetic fields and the plasma in the solar atmosphere? (Walter)