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Felix Aharonian (Dublin Institute for Advanced Studies, Dublin, Ireland;
Max-Planck-Institut for Kernphysis, Heidelberg, Germany)
Why very high energy gamma-rays?
Abstract:
I will discuss main objectives and motivations of gamma-ray
astronomy, its uniqueness and its to other branches of modern
astrophysics. The lecture ill consist of three parts: 1. Introduction -
general remarks; 2. Cosmic gamma ray source populations; 3. Gamma-ray
production mechanisms in astrophysical environments.
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Lorenzo Amati (INAF - Istituto di Astrofisica Spaziale e Fisica cosmica, Bologna, Italy)
GRB science with LOFT
Abstract:
LOFT is a satellite mission currently in Assessment Phase for
the ESA M3 selection. The payload is composed of the Large Area Detector
(LAD), with 2-50 keV energy band, a peak effective area of about 10 m2 and
an energy resolution better than 260 eV, and the Wide Field Monitor (WFM),
a coded mask imager with a FOV of several steradians, an energy resolution
of about 300 eV and a point source location accuracy of 1 arcmin in the
2-30 keV energy range. Based on preliminary considerations and estimates,
we show how the scientific performances of the WFM are particularly suited
to investigate some of the most relevant open issues in the study of GRBs:
the physics of the prompt emission, the spectral absorption features by
circum-burst material (and hence the nature of the progenitors), the
population and properties of XRFs, and the detection and rate of high.z
GRBs. Measurements of the early afterglow emission with the Large Area
Detector (LAD) may also be possible depending on the mission slewing
capabilities and TOO observations policy.
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Bruno Sversut Arsioli (Universidade Estadual de Campinas (UNICAMP), Instituto de Física Gleb Wataghin (IFGW), Brazil)
Active Galactic Nuclei: Blazars
The main characteristics of Blazars and a study of the new WISE-HSP sample.
Abstract:
Blazars are a class of active galactic nuclei (AGN) characterized by rapid and large
amplitude spectral variability, mainly due to the presence of a relativistic jet
pointing very close to the line of sight. The spectral emission of those objects
contain strong non-thermal radiation content along the whole energy band, from radio
to hard gamma-rays. Usually the observed radiation shows extreme properties,
mostly coming from relativistic amplification effects. Their spectral energy
distribution (SED) present a general shape composed of two bumps, one in the IR
to soft x-ray band and the other in the hard x-ray to gamma-rays. According to
the standard picture, the first peak is associated with the emission
of synchrotron radiation due to a relativistic electrons moving
in a feeble magnetic field and the second peak is associated with photons
which are Inverse-Compton (IC) scattered to higher energies by the same
electron population (seed photon ongoing IC can originate from the accretion disk
and the broad line region). In this context a blazar is classified as
High Synchrotron peaked (HSP) if the synchrotron peak frequency > 10^15 Hz.
Therefore, by definition HSP objects are very bright sources of X-rays and
compose a significant part of the Cosmic X-ray Background (CXB), (Giommi, 2008).
Observations have shown that HSPs are bright sources of high energy TeV photons
(nu > 10^25 Hz). They would be the dominant component of the TeV background,
a concept that is still not well established. According to low density distribution
of such objects in the sky, the TeV background would be composed by spread and
discrete sources, in contrast with the diffuse background light that is observed
for lower energies. Many questions are still under debate in what concerns
the absorption features at TeV energies. Therefore, it is a straight task to build
a complete catalog of HSP objects in order to provide important targets
for gamma-ray and TeV detection, allowing a better description of the blazars SEDs.
Clearly, within the motivations for identifying extremes AGNs are the possibility
of studding jet properties in extreme condition, and determining population
distribution of HSPs. Moreover, since they can be detected in a broad range
of redshifts, extreme blazars together with cluster of galaxies may be
an efficient tool for studding cosmological evolution (Puccetti, 2006).
The SEDs of HSP objects are extremely peculiar and no other type of extra-galactic
sources are known to posses such features. Imposing selection rules (like color-color
selection and multi-wavelength flux ratio limits) consistent with the HSP SEDs,
allow us to identify them within large amount of objects coming from all-sky surveys
(like WISE: Infrared all sky survey), and so to build up representative samples
with high selection efficiency.
The new WISE HSP will be presented. It contains about 450 objects, and its main
characteristics will be discussed.
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Diego Cáceres (Universidad Nacional de Colombia)
Equillibrium equations of magnetized white dwarfs
Abstract:
TBD
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Alessandro De Angelis (INFN-U.Udine/INAF/LIP-IST, Lisboa)
VHE cosmic γ rays and fundamental physics (with emphasis on photon propagation)
Abstract:
Introduction: why gamma rays? How?
Some results related to fundamental physics
What’s next
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Massimo Della Valle (Astronomical Observatory of Capodimonte, Naples, Italy)
Gamma-ray Bursts as Cosmological Rules
Abstract:
TBD
- Filippo Frontera (University of Ferrara)
Comptonization signatures in GRBs
Abstract:
Using a sample of 4 bright GRBs simultaneously detected with both the
BATSE experiment and the WFCs aboard BeppoSAX, it was possible to
perform a time resolved spectral analysis from 2 to 2000 keV, a band
still scarcely explored in the low energy part. In this peculiar energy
band, we tested the Epi-Liso correlation and some photospheric models:
the model proposed by Ryde and Pe'er (2009), the model proposed by
different authors (e.g., Guiriec et al. 2011) to describe some
time-resolved spectra of GRB detected with Fermi, in which a black body
is added to the Band function (e.g. Guiriec et al. 2011), and, last but
not least, the Comptonization model proposed by Titarchuk et al. (2012).
I will present some relevant results of our results.
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Kleinert Hagen (Free University of Berlin)
Conformal Gravity with Fluctuation-Induced Einstein Behavior at Long Distances
Abstract:
Conformal Gravity is renormalizable and has strong fluctuations capable of
generating spontanaously an Einstein term in the action, as a kind of
“dimensionlly transmuted coupling constant”. We show that this may
produce the correct long-range behavior of gravitational forces.
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Daniele Gregoris (Stockholm University)
The Stokes' law in general relativity: formulation and applications
Abstract:
Friction forces play an important role in many natural phenomena. Although widely understood
in classical mechanics, they have recently received new interest in the context of general
relativity. In this talk I will show how to write the Stokes formula using a general
relativistic formalism reobtaining the Poyting-Robertson expression and I will present
some applications in astrophysics and cosmology of this result. The motion of a body inside
a photon gas or a massive fluid is discussed inside the metric of Schwarzschild, Tolman
and Pant-Sah and Friedmann-Robertson-Walker respectively. In this last case I will discuss
the role of dissipative effects in the evaluation of peculiar velocities.
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Shabnam Iyyani (Stockholm University)
Fermi observations of the jet photosphere in GRBs: GRB110721A
Abstract:
Fermi Gamma Ray Space Telescope observations of the prompt
emission in gamma-ray bursts (GRBs) have provided evidence that several
different spectral features can be present in burst spectra. One such
feature is the emission from the jet photosphere, which has been shown
to play a significant role in the formation of the spectrum in several
strong bursts. In this talk, I will present characteristic Fermi bursts
which illustrate the various appearances that the photosphere can have
in GRBs. In particular, based on these observations, I will show how the
dynamics of the jet can be estimated and what we can learn about the
physical processes involved. I will also discuss geometrical and
physical processes that will broaden the photosphere spectrum that is
expected from a relativistic outflow and show how this can explain the
observations. Finally, I will compare these Fermi results with the
results found for the photospheric emission detected in CGRO BATSE
observations.
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Christoph H. Keitel (Max Planck Institute for Nuclear Physics (MPIK))
Extremely high-intensity laser interactions with fundamental quantum systems
Abstract:
Laser-vacuum interaction: Vacuum refractivity, matterless
double slit, pair creation
Laser-electron interaction:GeV laser colliders, pair creation,
radiative reaction, cascades
Laser-ion & nuclei interaction: ion acceleration for cancer
treatment, nuclear population transfer, laborat. astrophysics
 Presentation
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Hendrik Ludwig (University "La Sapienza ROMA")
Extraction of gravitational energy through strong electric fields
Abstract:
I will discuss models that are suitable to investigate the buildup of strong
electric fields in compact objects at equilibrium, oscillation and
collapse. These electric fields can provide a very effective and elegant
method of extracting gravitational energy via vacuum polarization.
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Nazzareno Mandolesi (INAF IASF BOLOGNA)
CMB Cosmology
Abstract:
I will review the most recent results on CMB Cosmology, including Planck 2013,
and give an outlook to future space missions in the field. Possible anomalies
in the Planck results will be briefly discussed.
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N. E. Mavromatos (King's College London and CERN-PH-TH)
Neutrinos and the Universe
Abstract:
I discuss various aspects of neutrino physics in extensions of the Standard
Model involving sterile (right-handed) neutrino states and their role
in Astrophysics, Cosmology and in general the Physics of the Early
Universe. In particular I will discuss aspects of oscillations, mass
generation, and interactions among sterile neutrinos and the standard model
sector with a view to study their role on Leptogenesis, Baryogenesis, Dark
Matter and Large scale structure of ther Universe. Concerning Dark Matter, I
will revisit the current constraints, including Planck Data, with a view to
support ideas that sterile neutrinos with masses of order of a few keV can play
the role of viable dark matter candidates, consistent with current data.
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Volker Perlick (ZARM, U. Bremen, Germany)
Gravitational Lensing beyond the weak-field approximation
Abstract:
Until a few years ago, the theory of gravitational lensing
was usually done in an approximation formalism, based on
the assumptions that the gravitational field is weak and that
bending angles are small. In principle, however, bending angles
can be arbitrarily large, i.e., light rays can make arbitrarily
many turns around compact massive objects. In this talk I
discuss a general formalism, based on an exact lens equation,
for describing gravitational lensing situations with arbitrarily
large bending angles. The general formalism is then applied
to Sagittarius A*, the object at the centre of our galaxy. In
particular, it is discussed how a black hole can be distinguished
from other compact objects by observing its 'shadow'. The
observation of the shadow of Sagittarius A* should be within
the reach of the Event Horizon Telescope and other upcoming
instruments.
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Mirzoyan Razmik (Max-Planck-Institute for Physics Munich, Germany)
Light in Our Life and in Science: How Do We Measure It
Abstract:
Light is playing a major role in our life, ~80% of information we obtain through
our visual perception. Also in physics measurement of light is playing a central role.
We are measuring Cherenkov light from gases (accelerator Cherenkov experiments),
atmosphere (air Cherenkov and air fluorescence experiments), in water (neutrino experiments),
from scintillation counters. Also in medical diagnostics detection of light is playing
a central role. Unlike human eyes the physicists developed sensors for measuring light
that are inferior in some senses like, for example, the dynamic range, but
they are superior in many other senses like, for example, the sensitivity and the speed.
The sensitivity of some special light sensors exceed that of human (and other living creature)
eyes by an order of magnitude, these can easily capture ultra-fast light flashes
and images and even display their development in time. Emission of light is accompanying
an enormous variety of processes, starting form stars and ending with human bodies.
Even the light sensors that are supposed only to detect light, are emitting their
own weak light. In my presentation I am going to dwell on the importance and
ways of measuring light, putting special accent on the state-of-the-art light sensors.
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Lev Titarchuk (University of Ferrara; ICRANET; Goddard Space Flight
Center)
X-ray spectral index correlations vs mass accretion rate in neutron star
and black hole X-ray binaries in their different spectral states. Theory vs observations
Abstract:
We present details of observations of neutron star (NS) and
black hole (BH) binaries and the first principle theory of X-ray spectral
formation in neutron star (NS) and black hole (BH) binaries.
We show our model predicts the spectral index
correlation vs mass accretion rate as in the case of NS as well in the BH case.
In BHs the spectral index should increase and then saturate with mass accretion
rate because the index as an inverse of Comptonization parameter Y and
Y-parameter saturates with the high mass accretion in the converging flow onto BH.
Comparison of this model prediction with X-ray observations shows that
in BH case the index, indeed, correlates and then saturates with mass accretion
rate. Moreover this index-mass accretion rate correlation allows us to estimate
BH masses and distance to the source. While in NS sources the observations shows that
the index stays the same independently of spectral state of the source
which can be possible if the energy release in the disk is always much smaller
of that at NS TL (boundary layer).
Vacuum pair-production in a classical electric field and an electromagnetic wave
Abstract:
Using semi-classical WKB-methods to treat the production of electron and
positron pairs by a strong electric field from the vacuum as a quantum
tunneling process we show derivation of a general expression for the
pair production rate in a z-dependent electric field E pointing in the z
direction. We also allow for a smoothly varying magnetic field B
parallel to E. The boundary effects of the confined fields on pair-production rates are exhibited. A
simple variable change in all
formulas leads to results for electric fields depending on time rather
than space. In addition, we discuss
tunnelling processes in which empty atomic bound states are
spontaneously filled by negative-energy
electrons from the vacuum under positron emission. Furthermore,
we show the calculation of the rate of electron-positron
pair-production from the vacuum in the presence of two external fields,
a strong (space- or time-dependent) classical field
and a monochromatic electromagnetic wave. We discuss
the possible medium effects on the rate in the presence of thermal
electrons, bosons, and neutral plasma of electrons and protons at a
given temperature and chemical potential. Using the rate formula, we
shown calculation of the rate enhancement
due to a laser beam, and discuss the possibility that a significant
enhancement may appear in a
plasma of electrons and protons with self-focusing properties.
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