Arefe Rasouli

Department of Physics, Sharif University of Technology

Seminar 1:  Investigating the Homogeneity and Isotropy of the Universe with Large-scale Structure Data and the Consistency of our Motion to CMB

Haniyeh Tadayoni

Department of Physics, Sharif University of Technology

Seminar 2: The study of the Kinematic and Clustering dipole using cosmological large-scale structure data

Nooshin Torabi

Department of Physics, Sharif University of Technology

Seminar 3: How PBHs and NFW dark matter halos change the number of strongly lensed GW events?

یکشنبه 24 تیر 1403، ساعت 10:00

Sunday 14 July 2024 – 10:00 Tehran Time 

Hybrid Seminar

دانشکده فیزیک – طبقه پنجم – کلاس 512 Physics Department fifth floor – Room 512   /

https://vc.sharif.edu/ch/cosmology

گزینه ورود به صورت مهمان – Enter as a Guest

Abstract of the Seminar 1: The standard ΛCDM model is built upon the cosmological principle, which states that the universe on large scales is homogeneous and isotropic when averaged over sufficiently large scales. However, the cosmic microwave background (CMB) displays a dipole anisotropy at a level of ΔT/T ∼ 10^-3. This dipole is commonly interpreted as owing to our motion with respect to the CMB rest frame. A model-independent approach to validate this kinematic hypothesis is to determine the dipole moment in the angular distribution of the large-scale structure at lower redshifts. Previous observations of the dipole anisotropy in the sky distribution of radio galaxies and quasars drawn from NVSS and WISE catalogs indicate a discrepancy with the CMB dipole, both in terms of direction and amplitude.

In this study, we investigate this inconsistency using large-scale cosmic data. Along with analyzing the Doppler effect, we will also explore the average peculiar velocity of structures and compare it with the standard model. In order to determine the true peculiar velocity, we are trying to distinguish between the kinematic and clustering dipoles. Additionally, we will look into new methods for measuring kinematic velocity and examine the impact of alternative models in resolving this discrepancy.

Abstract of the Seminar 2: The ΛCDM Standard Model of Cosmology relies on the cosmological principle, which asserts that the universe is homogeneous and isotropic on large scales, around 100 megaparsecs, regardless of the observer’s location. Observational evidence from the Cosmic Microwave Background (CMB) radiation, despite minor temperature fluctuations of 1 part in 10,000 on small angular scales, supports this principle. However, the CMB exhibits a dipole anisotropy at a level of  which is significantly larger than the smaller-scale anisotropies. This dipole is often interpreted as the result of our motion relative to the CMB rest frame, making its study essential for understanding the universe’s dynamics and the cosmological principle’s validity.

The CMB dipole’s origin is debated, with some attributing it to the Solar System’s motion relative to the CMB rest frame and others to early universe phenomena. Within the ΛCDM framework, the CMB dipole’s characteristics should align with model predictions, helping verify assumptions about dark matter, dark energy, and the universe’s large-scale structure.

Recent studies have explored the origin of the Cosmic Microwave Background (CMB) dipole and its implications for the ΛCDM model. Some research attributes the CMB dipole to the Doppler effect from our movement relative to the CMB frame, while observations of large-scale structures (LSS) have shown deviations from this kinematic interpretation. Additionally, a study using the CatWISE2020 catalog found the dipole amplitude to be more than twice the expected value, raising questions about the cosmological principle in the ΛCDM model and emphasizing the need for a better understanding of the CMB dipole’s origin. Moreover, recent studies have introduced the concept of a clustering dipole, suggesting it may explain discrepancies between the large-scale structure dipole and the CMB dipole, and should be considered in measurements.

In this seminar, we will examine both dipoles, using large-scale structure data such as NVSS to evaluate their magnitudes and analyze the differences in results between linear and non-linear regimes.

Abstract of the Seminar 3: Massive objects in the universe cause deflection of the light rays on their path from the source to the observer; this phenomenon called Gravitational Lensing happens to gravitational waves similar to light rays.

In the case of Strong lensing, creating two or even multiple images with different magnifications of an event is possible. The images could reach the observer with a time delay. Cross section of Strong lensing depends on the lens model and the corresponding Einstein radius.

Strong lensing statistics could provide us information about the expected number of lensed events that reach an observer, and the time delay distribution, which helps us determine if we could detect separate images with a given detector and observation duration.

To determine the expected number of lensed events we need to calculate the merger rate of black holes, the probability of lensing which is capsulated in optical depth, and the detectors’ characteristics. Different lens models could lead to different optical depths and thus change the number of lensed events.  Considering dark matter halos as diffuse objects with NFW profile mass density would reduce the probability of lensing compared to the point mass approximation.

The existence of Primordial black holes, which has been a subject of debate in the field, could affect the lensing rate due to acting like a point mass lens and also being a source as an outcome of mergers. Furthermore, because of the range of frequencies that we detect gravitational waves, wave optics can play an important role in lensing.

In this talk, we investigate how considering PBHs as a fraction of dark matter in the universe would change the expected number of lensed GW events and compare the effect of halos by considering different mass profiles for them. We also review the current research in this field.

Haidar Sheikhahmadi

School of Astronomy, Institute for Research in Fundamental Sciences-IPM

Self-Interacting QFT in Curved Backgrounds, the Bubble Loop Corrections

Abstract:  We consider a general Lagrangian for a massive scalar field with a conformal coupling in the dS background and study the quantum corrections from bubble loop diagrams. Employing a dimensional regularization scheme, we calculate the regularized zero-point energy density, pressure, and the trace of the energy-momentum tensor. It is shown that the classical relation of trace for the vacuum stress-energy tensor receives quantum anomaly correction which depends on the mass and the conformal coupling, while the consistency relation of zero-point energy does hold. We calculate the density contrast associated with the vacuum zero-point energy and show that perturbations are of the order of background values indicate an inhomogeneous and non-perturbative distribution of the zero-point energy. Even more, we calculate the bispectrum associated with the distribution of the zero-point energy and pressure and show that they are highly non-Gaussian. In the next step, incorporating the perturbative in-in formalism, we extend our analysis to self-interacting fields with a general potential of even orders of the field. We again calculate the quantum corrections in the vacuum zero-point energy and pressure for these fields as well. We then investigate the equation of state corresponding to these quantum corrections and examine the scaling of the divergent terms in the vacuum zero-point energy and pressure associated with the dimensional regularization scheme. We discuss some interesting aspects of free and interacting vacua and their relation as well.

یکشنبه 6 خرداد 1403، ساعت 17:00

Sunday 26 May 2024 – 17:00 Tehran Time

Hybrid Seminar

دانشکده فیزیک – طبقه اول – کلاس فیزیک 3 Physics Department – first floor – Room Physics 3   /

https://vc.sharif.edu/ch/cosmology

گزینه ورود به صورت مهمان – Enter as a Guest

Raihaneh Moti

School of Astronomy, Institute for Research in Fundamental Sciences-IPM

On the GravoThermo Memory 

Abstract: In this presentation, the concepts discussed in arXiv:2307.04151 will be explored. First, I will review the gravitational memory effect. Then, the thermodynamic properties of a freely falling ensemble of gyroscopes after the passage of a weak gravitational wave will be discussed. Due to the precession memory effect, the thermodynamic quantities will experience a change because of the space-time perturbation. This GravoThermo memory effect potentially can be used for the detection of gravitational waves.

  یکشنبه 30 اردیبهشت 1403، ساعت 17:00

Sunday 19 May 2024 – 17:00 Tehran Time

Hybrid Seminar

دانشکده فیزیک – طبقه اول – کلاس فیزیک 3 Physics Department – first floor – Room Physics 3  / 

https://vc.sharif.edu/ch/cosmology

گزینه ورود به صورت مهمان – Enter as a Guest

Amirmohammad Chegeni

Department of Physics and Astronomy “Galileo Galilei”, University of Padova

Clusternets: A deep learning approach to probe clustering dark energy

Abstract: Machine Learning (ML) algorithms are becoming popular in cosmology for extracting valuable information from cosmological data. In this paper, we evaluate the performance of a Convolutional Neural Network (CNN) trained on matter density snapshots to distinguish clustering Dark Energy (DE) from the cosmological constant scenario and to detect the speed of sound ($c_s$) associated with clustering DE. We compare the CNN results with those from a Random Forest (RF) algorithm trained on power spectra. Varying the dark energy equation of state parameter $w_{\rm{DE}}$ within the range of -0.7 to -0.99, while keeping $c_s^2 = 1$, we find that the CNN approach results in a significant improvement in accuracy over the RF algorithm. The improvement in classification accuracy can be as high as 40\% depending on the physical scales involved. We also investigate the ML algorithms’ ability to detect the impact of the speed of sound by choosing $c_s^2$ from the set $\{1, 10^{-2}, 10^{-4}, 10^{-7}\}$ while maintaining a constant $w_{\rm DE}$ for three different cases: $w_{\rm DE} \in \{-0.7, -0.8, -0.9\}$. Our results suggest that distinguishing between various values of $c_s^2$ and the case where $c_s^2=1$ is challenging, particularly at small scales and when $w_{\rm{DE}}\approx -1$. However, as we consider larger scales, the accuracy of $c_s^2$ detection improves. Notably, the CNN algorithm consistently outperforms the RF algorithm, leading to an approximate 20\% enhancement in $c_s^2$ detection accuracy in some cases.

یکشنبه23 اردیبهشت 1403، ساعت 17:00

Sunday 12 May 2024 – 17:00 Tehran Time

Hybrid Seminar

دانشکده فیزیک – طبقه اول – کلاس فیزیک 3 /Physics Department – first floor – Room Physics 3   

https://vc.sharif.edu/ch/cosmology

گزینه ورود به صورت مهمان – Enter as a Guest

Mohammad Ansari

Department of Physics, K.N. Toosi University of Technology, Tehran, Iran;

School of Astronomy, Institute for Research in Fundamental Sciences (IPM)

The nearest neighbor statistics in cosmology

Abstract: The statistic of matter in non-linear regimes is non-Gaussian, and the two-point correlation function doesn’t have all the information in it. Introducing innovative quantities, along with the two-point correlation function is useful for non-linear regimes. In this direction we introduce the nearest neighbor statistics and show how this function could help us to constrain parameters and cosmological models (such as neutrino mass and fuzzy dark matter). In addition, for the first time we introduce the angle between nearest neighbors to cosmology. Noting that this quantity depends on angles and geometry (and not distances), exploring it may open up new horizons to cosmology. For example, by this quantity we can classify different cosmic web finder approaches.

یکشنبه16 اردیبهشت 1403، ساعت 17:00

Sunday 5 May 2024 – 17:00 Tehran Time

Hybrid Seminar

دانشکده فیزیک – طبقه اول – کلاس فیزیک 3 Physics Department – first floor – Room Physics 3  / 

https://vc.sharif.edu/ch/cosmology

گزینه ورود به صورت مهمان – Enter as a Guest

Farnik Nikakhtar

Department of Physics, Yale University, USA

Year 1 results of the Dark Energy Spectroscopic Instrument with a focus on Baryon Acoustic Oscillations 

Abstract: The Dark Energy Spectroscopic Instrument (DESI) collaboration is conducting a five-year redshift survey of 40 million extragalactic sources across 14,000 square degrees of the northern sky, up to a redshift of 4, using the Mayall 4-meter telescope at Kitt Peak National Observatory. One of its primary goals is to precisely and accurately measure the cosmic expansion history through measurements of baryon acoustic oscillations (BAO). In this talk, I will discuss the measurements from DESI’s first-year Baryon Acoustic Oscillations, utilizing the distributions of galaxies (and quasars) over a redshift range of 0.1-2. For the first time, the DESI team employed catalog-level blinding in the BAO analysis to prevent confirmation bias in determining the expansion history. The resultant aggregate precision of the DESI Year 1 BAO analysis surpasses that of all previous galaxy surveys combined, prior to DESI.

یکشنبه  9 اردیبهشت 1403، ساعت 17:00

Sunday 28 April 2024 – 17:00 Tehran Time

Hybrid Seminar

دانشکده فیزیک – آمفی تئاتر (تالار جناب) /Physics Department – Amphitheater  (Jenab Hall)   

https://vc.sharif.edu/ch/cosmology

گزینه ورود به صورت مهمان – Enter as a Guest

Ebrahim Siri

Department of Physics, Sharif University of Technology

Thermodynamic properties of a relativistic Bose gas under rigid rotation

Abstract: The investigation of the impact of rotation on fermionic and bosonic systems has recently become a significant area of research in finite temperature field theory. In this work, we focus on a system of relativistic Bose gas subjected to a rigid rotation and analyze its thermodynamic properties. First, we introduce the rigid rotation metric and derive the solutions of the Klein-Gordon equation in cylindrical coordinates. We then calculate the propagator of a rotating bosonic system by making use of the generalized Fock-Schwinger proper-time method. Using the imaginary time formalism at finite temperature, we compute the thermodynamic potential of the system up to the first order of perturbative expansion. Additionally, we determine the nonperturbative ring contribution to the thermodynamic potential. Utilizing this potential, we calculate some thermodynamic quantities, such as pressure, energy density, entropy density, and angular momentum density. The obtained results show that the moment of inertia becomes negative in certain regimes of the parameter space. Our results are similar to the recent findings for the moment of inertia of a rotating gluonic plasma, where a supervortical temperature is introduced.

یکشنبه  2 اردیبهشت 1403، ساعت 17:00

Sunday 21 April 2024 – 17:00 Tehran Time

Hybrid Seminar

دانشکده فیزیک – طبقه اول – کلاس فیزیک 3/  Physics Department – first floor – Room Physics 3    

https://vc.sharif.edu/ch/cosmology

گزینه ورود به صورت مهمان – Enter as a Guest

Bahar Nikbakht

School of Astronomy, Institute for Research in Fundamental Sciences (IPM)

Non-Gaussianity consistency relations and their consequences for the peaks

Abstract: Strong deviations from scale invariance and the appearance of high peaks in the primordial power spectrum have been extensively studied for generating primordial black holes (PBHs) or gravitational waves (GWs). It is also well-known that the effect of non-linearities can be significant in both phenomena. In this study, we introduce a general single-field consistency relation that relates the amplitude of non-Gaussianity in the squeezed limit  to the power spectrum and remains valid when almost all other consistency relations are violated.

Then we discuss the general and model-independent consequences of the consistency relation on the behavior of  at different scales.

As an implication of our results, we argue that non-linearities can shift or extend the range of scales responsible for the production of PBHs or GWs, relative to the window as determined by the largest peak of the power spectrum, and may also open up new windows for both phenomena.

یکشنبه 26 فروردین 1403، ساعت 17:00

Sunday 14 April 2024 – 17:00 Tehran Time

Hybrid Seminar

دانشکده فیزیک – طبقه اول – کلاس فیزیک 3 /Physics Department – first floor – Room Physics 3   

https://vc.sharif.edu/ch/cosmology

گزینه ورود به صورت مهمان – Enter as a Guest

Samaneh Sarbaz

Department of Physics, Sharif University of Technology

Seminar 1: Radio Astronomy: A brief report on the topics covered in the I_HOW/IAU radio astronomy workshop

Zahra Tabatabaee

Department of Physics, Sharif University of Technology

Seminar 2: The dynamics of FRW universe in scalar-Tensor-Vector gravity

Abstract 1: Today, radio astronomy is one of the best methods for observing the universe. A wide range of topics, such as star and planet formation, galaxy formation and evolution and interstellar and intergalactic medium can be ideally studied using these radio data. In September 2023,IAU/I-HOW Radio Astronomy was held at Erciyes University, Kayseri, Türkiye. One of the objectives of this Workshop was to prepare young researchers to learn how to analyse radio data from radio telescopes such as ALMA and VLA. In our upcoming talk, I will discuss radio astronomy. I am going to talk about the introduction of radio telescopes and analyzing radio data. This talk will be a brief report on the topics covered in the I_HOW/IAU radio astronomy workshop. 

Abstract 2: The Scalar-Tensor-Vector-Gravity (STVG), also known as MOG (Modified Gravity), has been proposed as a solution to the dark matter problem. In this talk, a gauge-invariant theory for MOG will be introduced through a symmetry-breaking mechanism at low temperatures, where gravitational attraction is governed by an effective gravitational constant. The modified Friedmann equation and scale factor evolution for this theory will be discussed. Finally, it will be mentioned that this theory has the potential to alter the dynamics of the early and late Universe.

یکشنبه 20 اسفند 1402، ساعت 17:00

Sunday 10 March 2024 – 17:00 Tehran Time

Hybrid Seminar

دانشکده فیزیک – طبقه اول – کلاس فیزیک 3 Physics Department – first floor – Room Physics 3  / 

https://vc.sharif.edu/ch/cosmology

گزینه ورود به صورت مهمان – Enter as a Guest