inars

 

GRAVITY THEORY SEMINARS FALL 2011


The seminars take place every Wednesday at 3:15 pm in Room 4102 unless otherwise stated below. For more information about GRT group seminars contact Manuel Tiglio (Physics 4205E and CSIC 4129). For information concerning the Elementary Particle Theory group seminars see the EPT seminar page, the Theoretical Quarks, Hadrons, Nuclei group seminars see the TQHN seminar page, and scheduled seminars in the UMD Physics Department see the Department seminar pages. The webpages of the UMD-NASA Goddard Joint Space-Science Institute and the Maryland Center for Fundamental Physics also hold regular events of interest to the group.

Seminars from previous semesters can be found here: spring 2002, fall 2002, spring 2003, fall 2003, spring 2004, fall 2004, spring 2005, fall 2005, spring 2006, fall 2006, spring 2007, fall 2007, spring 2008, fall 2008, spring 2009, fall 2009, 2010, spring 2011.

 

Date, time and place


Speaker, affiliation, title and abstract


JSI mini-symposium

Friday Sep. 16, 2:00-6:00pm.
Room 2400 Computer and Space Sciences Building

"JSI Scientists Overview"


Bernard Kelly (NASA Goddard): "Gravitational-wave data analysis with spinning merger-ringdown waveforms"

Yi Pan (UMD): "Expanding effective-one-body models in binary black hole parameter space"

Scott Field (UMD):  "A reduced basis representation for chirp and ringdown gravitational wave templates"


Tyson Littenberg (NASA Goddard and UMD):  "White dwarf binary science in the post-LISA era"


Tamara Bogdanovic (UMD): "Electromagnetic Signatures of Supermassive Black Hole Mergers"


Margaret Trippe (UMD): "Our Spin on Supermassive Black Holes"


Simona Giacintucci (UMD): "Diffuse radio emission from the intracluster medium - the low frequency viewpoint"


David B. Fisher (UMD): "Bulges in the Nearby Universe"


Alexandre Le Tiec (UMD): "Periastron Advance in Black Hole Binaries"


Sam Gralla (UMD): "Gravitational Self-Force in Extreme Mass-Ratio Inspiral"


James Van Meter (NASA Goddard): "Invariant computation of spin and other properties of numerically simulated black holes"



Astro Theory Lunch
Monday, Sep. 26

11:30am
1255 (Library room) CSS (Computer and Space Sciences) Building


Umberto Cannella
Department of Physics, University of Maryland

"Testing gravity with gravitational waves: a field-theoretical perspective"

Abstract: So far experiments of relativistic gravity have probed dynamical regimes only up to order "(v/c)^5" in the post-Newtonian expansion, which corresponds to the very first term of the radiative sector in General Relativity. In contrast, by means of gravitational-wave astronomy, one aims at testing gravity up to (v/c)^(12)! It is then relevant to envisage testing frameworks which are appropriate to this strong-field/radiative regime.
Using a field theory approach, gravitational interactions are described by Feynman diagrams in which classical gravitons interact with matter sources and among themselves. Tagging the self-interaction vertices of gravitons with parameters it is possible, for example, to translate the measure of the period decay of Hulse-Taylor pulsar into a constraint on the three-graviton vertex at the 0.1% level. With future observations of gravitational waves, higher order graviton vertices can in principle be constrained through a Fisher matrix analysis.


Monday, Sep. 26
1:30pm
Room 4102 Physics


Bruno Giacomazzo
Department of Astronomy, University of Maryland, and NASA Goddard


"Magnetized binary neutron stars"

Abstract: Binary neutron stars are among the most powerful sources of gravitational waves that will be detected by ground-based interferometers, such as advanced Virgo and LIGO, and they are also thought to be behind the central engine of short gamma-ray bursts. I will report on the work I have done in the last two years by using my fully general relativistic magnetohydrodynamic code Whisky in simulating binary neutron star systems during the last stages of inspiral, merger and eventual collapse to a black hole surrounded by an hot and magnetized torus. I will in particular describe the gravitational wave signal emitted by these sources and their possible role in powering short gamma-ray bursts.



EPT Seminar
Monday, Sep. 26

3:00pm
Room 4102 Physics


Yasunori Nomura
University of California, Berkeley

"Physical Predictions in the Quantum Multiverse"

Abstract: I describe how quantum mechanics plays a crucial role in defining probabilities (the "measure") in the multiverse. The resulting picture leads to a dramatic change of our view on spacetime and gravity, and provides complete unification of the eternally inflating multiverse and many worlds in quantum mechanics. The latest result on the distribution of the cosmological constant is also presented. The talk is based mainly on arXiv:1104.2324 (but also on arXiv:1107.3556).



MCFP Colloquium
Thursday, Sep. 29

4:00pm
Room 1201 Physics


Sergei Dubovsky
New York University

"Exploring the String Axiverse with Astrophysical Black Holes?" 

Abstract: Combining the QCD axion as a solution to the strong CP problem with the properties of axions in string theory suggests the simultaneous presence of many ultralight axions with masses homogeneously distributed over the log scale---the "Axiverse". These axions give rise to a number of distinctive observational signatures, including the rotation of the CMB polarizations at the level within the reach of the Planck satellite, and steps in the dark matter power spectrum. A surprising evidence for the axions with masses in the range 10^(-22) to 10^(-10) eV may come from observations of astrophysical black holes through the Penrose superradiance process. When the axion Compton wavelength is of order of the black hole size, the axions develop "superradiant" atomic bound states around the black hole "nucleus". Their occupation number grows exponentially by extracting rotational energy from the ergosphere, culminating in a rotating Bose-Einstein axion condensate emitting gravitational waves. This mechanism creates mass gaps in the spectrum of rapidly rotating black holes and gives rise to a distinctive gravity wave signal. In particular, the QCD axion with the decay constant of order the GUT scale affects the dynamics of stellar mass black holes. This opens a possibility for a discovery of the QCD axions through ongoing measurements of black hole spins. The corresponding gravity wave signal may be within the reach of the Advanced LIGO.




Monday, Oct. 3
Joint seminar with Particle Theory
3:00pm
Room 4102 Physics


Alejandro Satz
Department of Physics, University of Maryland

"Nonlocalities in the Quantum Gravity effective action renormalization flow"

Abstract: The renormalization group flow of the effective average action has been intensively studied in quantum gravity with the hope of exhibiting a non-Gaussian fixed point that renders the theory asymptotically safe. To make concrete calculations possible, most research has focused upon truncations of the effective action restricting it to local terms. In this talk I present some preliminary results concerning the RG flow of nonlocal terms, within a one-loop approximation and in a weak field expansion. The flowing nonlocal effective action reduces to the standard effective action of low-energy perturbative quantum gravity in the appropiate limit, and can be used to compute quantum corrections to the Newtonian potential, which will be described and discussed.
(based on http://arxiv.org/abs/1006.3808)


Monday, Oct. 3
Ph D thesis defense
4:00pm
Place: 4316 Physics


Jonah Kanner
Department of Physics, University of Maryland

"LOOC UP: Seeking Optical Counterparts to Gravitational Wave Signals"



Monday, Oct. 10
1:30pm

Room 4102 Physics


Sarah Caudill
Department of Physics and Astronomy, Louisiana State University


TBA


Monday, Oct. 17

1:30pm
Room 4102 Physics


Sam Gralla
Department of Physics, University of Maryland

Motion of Small Bodies: Derivation and Surprises

Astract: A formalism developed jointly with R Wald has proven remarkably successful in (rigorously) deriving equations of motion for "small bodies" in General Relativity and other classical field theories.  The basic idea is to consider a one-parameter-family of spacetimes in which not only the size of the body but also its mass and charges are taken to zero, a limit which is physical in the sense that it respects the Schwarzschild limit on the size of a body and keeps the self-energy finite, and mathematically convenient in that it avoids the usual difficulties with point particles.  I will describe the formalism and its application to 1) self-force and spin-force effects in general relativity, 2) self, spin and dipole forces in classical electromagnetism, and 3) lowest-order motion in a general diffeomorphism-covariant Lagrangian field theory.  Some of the surprises have been: a key role played by a "parity condition" due to Regge and Teitelboim, a universal form for the equation of motion across Lagrangian field theories, the appearance of "extra terms" in the force on a classical electric or magnetic dipole, and the existence of a "kinematical effect" that modifies the motion of all spinning bodies, giving rise to "bobbing behavior" (as observed in simulations of spinning black hole binaries) in ordinary systems like billiard balls connected by a string.



Monday, Oct. 24
1:30pm
Room 4102 Physics


Umberto Cannella
Department of Physics, University of Maryland

TBA


Monday, Oct. 31

1:30pm
Room 4102 Physics



Monday, Nov. 7
1:30pm
Room 4102 Physics


Jennifer Seiler
NASA Goddard

"Binary Orbital Dynamics from Analysis of Spherical Harmonic Modes of
Gravitational Waves"

Abstract:
I will present an analysis of the properties of binary black hole inspirals obtainable from the spherical harmonic modes of the emitted gravitational waveforms. Using well-know methods we extract the final spins, kicks, and mass of the merged black holes. By the energy loss from the waves we can estimate the rate of inspiral, and from the asymmetric spherical harmonic modes we can obtain the orbital frequency. Then, using Wigner rotation to find the angles that minimize the asymmetric spherical harmonic modes we can obtain the angles of the precession of the system. Effectively we are finding rotation angles that would make the line from the observer to the system always line up with the orbital angular momentum. Thus we show that most of the astrophysical qualities and dynamics from precessing binary black hole systems can be reconstructed from observed waveforms.


Monday, Nov. 14
1:30pm

Room 4102 Physics




Monday, Nov. 21

1:30pm
Room 4102 Physics

Jorg Frauendiener (to be confirmed)
Department of Mathematics and Statistics, University of Otago, New Zealand

TBA

Monday, Nov. 28
1:30pm
Room 4102 Physics

 
Liangcheng Tu
Huazhong University of Science and Technology, Wuhan, China

"Progress in testing Newtonian inverse square law in short range with dual-modulation torsion balance"

Abstract:
This talk will have two parts: a brief introduction of the HUST Gravitation Experiment Group and a detailed report of the Newtonian inverse square law (ISL) tests that have been performed and are being performed in the HUST group. In the second part, first, general motivation and the current status of the ISL test at short range will be discussed; then, our experiments at sub-millimeter to millimeter range will be introduced.  We use a torsion balance to sense the force from a gap-modulated source.  The goal of the experiment is to improve the limit of the ISL by at least an order of magnitude.  Finally, our future experimental schemes, to test the ISL at micrometer to sub-millimeter range with a density modulated source and a torsion balance with AFM, will be presented.


Monday, Dec. 5

1:30pm
Room 4102 Physics

Alexandre Le Tiec
Department of Physics, University of Maryland


TBA


Monday, Dec. 12

1:30pm
Room 4102 Physics


 


Home     People      Ph.D. Program      Available Positions      Related Links


Back to the UM Physics Department Home Page

Back to the University of Maryland Home Page


 

Send comments to: tiglio AT umd.edu