Presentation is loading. Please wait.

Presentation is loading. Please wait.

Observational Constraints on Sudden Future Singularity Models Hoda Ghodsi – Supervisor: Dr Martin Hendry Glasgow University, UK Grassmannian Conference.

Published byHolly Rose Modified over 9 years ago

Similar presentations

Presentation on theme: "Observational Constraints on Sudden Future Singularity Models Hoda Ghodsi – Supervisor: Dr Martin Hendry Glasgow University, UK Grassmannian Conference."— Presentation transcript:

1 Observational Constraints on Sudden Future Singularity Models Hoda Ghodsi – Supervisor: Dr Martin Hendry Glasgow University, UK Grassmannian Conference in Fundamental Cosmology Szczecin, Poland, September 2009

2 Outline Concordance Cosmology Overview Sudden Future Singularity Theory Observational Constraints Method Results Conclusions and Future Directions

3 Concordance Cosmology Cosmological observations of most importantly the Cosmic Microwave Background Radiation (CMBR), the Large Scale Structure and SNe Ia have helped establish a standard Concordance Cosmology with the following characteristics: Evolution: Accelerating expansion driven by a form of Dark Energy Geometry: Flat Contents: 74% Dark Energy, 22% Dark Matter, 4% Baryonic Matter Age: 13.7 Gyr old Fate: Empty de-sitter type fate Courtesy: http://map.gsfc.nasa.gov/ Courtesy: http://abyss.uoregon.edu/

4 Sudden Future Singularity Model Barrow ( Class. Quantum Grav. 21, L79 ) discovered a new type of possible end to the Universe (assuming no equation of state) which violated the dominant energy condition only He called them Sudden Future Singularities Pressure singularities Barrow then constructed an example model which could accommodate an SFS with scale factor of the form:,

5 Sudden Future Singularity Model Occurrence regardless of curvature, homogeneity or isotropy of the universe Pressure behaviour satisfies observation: current acceleration possible log (pressure) time Note that no explicit Dark Energy component has been assumed to exist. Dabrowski calls the cause some “pressure driven dark energy”.

6 Observational Constraints SNIa redshift-magnitude relation Deceleration parameter The Location of the CMBR Acoustic Peaks Baryon Acoustic Oscillations Age of the Universe

7 SNIa redshift-magnitude relation Previously it was shown by Dabrowski et al. (2007) that the SFS SNIa redshift-magnitude relation matches observations and the Concordance model. Test redone with 182 SNe Ia as compiled by Riess et al. (2007) In the Gold data set  same results were achieved. Luminosity distance is given by: where The distance modulus is defined as: Distance modulus vs. log(redshift) for the SFS and Concordance models as compared with SNIa data from Tonry et al. (2003) ‘Gold’ sample and Astier et al. (2006) SNLS sample. Graph from Dabrowski et al. (2007).

8 Deceleration parameter q(z) z SFS Model Concordance Model Concordance Model parameters: SFS Model parameters:

9 CMBR acoustic peaks Shift parameter, : Angular diameter distance to the last scattering surface (LSS) divided by Hubble horizon at the decoupling epoch The apparent size of the sound horizon at recombination Can be found using the formula: Acoustic scale, : Angular diameter distance to the LSS divided by sound horizon at the decoupling epoch Can be calculated using the formula: The observed values of these parameters are taken from Komatsu et al. (2008) Courtesy: http://map.gsfc.nasa.gov/

10 Baryon Acoustic Oscillations Cosmological perturbations excite sound waves in the early universe photon-baryon plasma  competition between gravity and radiation pressure. These oscillations leave their imprint on matter distribution now Natural standard ruler  useful distance indicators now Can be used to constrain the quantity known as the distance parameter,, well: Angular scale of oscillations Observed value taken from Komatsu et al. (2008) Courtesy: http://cmb.as.arizona.edu/ Courtesy: http://www.sdss3.org/

11 Age of the Universe Using the standard Friedmann equation, the age of the Universe is calculated from: where and Corresponding age for the SFS model was calculated Observed value for the age: from the globular cluster estimates as Krauss and Chaboyer (2003) present, i.e. no cosmology assumed Hubble constant from the HST Key Project as given by Freedman et al. (2001) which assumes only local cosmology Therefore Hubble constant constraint also included

12 Method Used statistics to fit model parameters to data Theoretically to obtain an SFS: and a currently accelerating universe: To comply with early universe requirements: For, was used as the fraction of the time to an SFS elapsed 2d parameter space of search while keeping constant

13 Results n δ

14 SN AllAge AR

15 BAOSNIa CMBR n δ

16 BAOSNIa CMBR n δ

17 BAO SNIa CMBR n δ

18 BAO SNIa CMBR n δ

19 BAO SNIa CMBR n δ

20 BAOSNIa CMBR n δ

21 Results BAOSNIa CMBR n δ

22 Results BAOSNIa CMBR n δ

23 BAOSNIa CMBR n δ

24 Conclusions and Future Directions The example SFS model (with kept constant) investigated has been shown not to be compatible with current data. With the data analysis tools set up we are planning to continue our research by working on other non- standard models like the GR averaging model proposed by Wiltshire (2007).

Download ppt "Observational Constraints on Sudden Future Singularity Models Hoda Ghodsi – Supervisor: Dr Martin Hendry Glasgow University, UK Grassmannian Conference."

Similar presentations

Seeing Dark Energy (or the cosmological constant which is the simplest form of DE) Professor Bob Nichol (ICG, Portsmouth)

Seeing Dark Energy (or the cosmological constant which is the simplest form of DE) Professor Bob Nichol (ICG, Portsmouth)
Prospects for the Planck Satellite: limiting the Hubble Parameter by SZE/X-ray Distance Technique R. Holanda & J. A. S. Lima (IAG-USP) I Workshop “Challenges.

Prospects for the Planck Satellite: limiting the Hubble Parameter by SZE/X-ray Distance Technique R. Holanda & J. A. S. Lima (IAG-USP) I Workshop “Challenges.
Dark Energy. Conclusions from Hubble’s Law The universe is expanding Space itself is expanding Galaxies are held together by gravity on “small” distance.

Dark Energy. Conclusions from Hubble’s Law The universe is expanding Space itself is expanding Galaxies are held together by gravity on “small” distance.
Current Observational Constraints on Dark Energy Chicago, December 2001 Wendy Freedman Carnegie Observatories, Pasadena CA.

Current Observational Constraints on Dark Energy Chicago, December 2001 Wendy Freedman Carnegie Observatories, Pasadena CA.
Yashar Akrami Modern Cosmology: Early Universe, CMB and LSS/ Benasque/ August 17, 2012 Postdoctoral Fellow Institute of Theoretical Astrophysics University.

Yashar Akrami Modern Cosmology: Early Universe, CMB and LSS/ Benasque/ August 17, 2012 Postdoctoral Fellow Institute of Theoretical Astrophysics University.
CMB: Sound Waves in the Early Universe Before recombination: Universe is ionized. Photons provide enormous pressure and restoring force. Photon-baryon.

CMB: Sound Waves in the Early Universe Before recombination: Universe is ionized. Photons provide enormous pressure and restoring force. Photon-baryon.
This has led to more general Dark Energy or Quintessence models: Evolving scalar field which ‘tracks’ the matter density Convenient parametrisation: ‘Equation.

This has led to more general Dark Energy or Quintessence models: Evolving scalar field which ‘tracks’ the matter density Convenient parametrisation: ‘Equation.
Observational Cosmology - a laboratory for fundamental physics MPI-K, Heidelberg 24.11.2011 Marek Kowalski.

Observational Cosmology - a laboratory for fundamental physics MPI-K, Heidelberg Marek Kowalski.
Cosmological Structure Formation A Short Course

Cosmological Structure Formation A Short Course
Observational Cosmology - a unique laboratory for fundamental physics Marek Kowalski Physikalisches Institut Universität Bonn.

Observational Cosmology - a unique laboratory for fundamental physics Marek Kowalski Physikalisches Institut Universität Bonn.
Lecture 2: Observational constraints on dark energy Shinji Tsujikawa (Tokyo University of Science)

Lecture 2: Observational constraints on dark energy Shinji Tsujikawa (Tokyo University of Science)
Cosmology Overview David Spergel. Lecture Outline  THEME: Observations suggest that the simplest cosmological model, a homogenuous flat universe describes.

Cosmology Overview David Spergel. Lecture Outline  THEME: Observations suggest that the simplest cosmological model, a homogenuous flat universe describes.
PRE-SUSY Karlsruhe July 2007 Rocky Kolb The University of Chicago Cosmology 101 Rocky I : The Universe Observed Rocky II :Dark Matter Rocky III :Dark Energy.

PRE-SUSY Karlsruhe July 2007 Rocky Kolb The University of Chicago Cosmology 101 Rocky I : The Universe Observed Rocky II :Dark Matter Rocky III :Dark Energy.
CMB as a physics laboratory

CMB as a physics laboratory
Physics 133: Extragalactic Astronomy ad Cosmology Lecture 6; January 27 2014.

Physics 133: Extragalactic Astronomy ad Cosmology Lecture 6; January
1 L. Perivolaropoulos Department of Physics University of Ioannina Open page

1 L. Perivolaropoulos Department of Physics University of Ioannina Open page
Lecture 1: Basics of dark energy Shinji Tsujikawa (Tokyo University of Science) ``Welcome to the dark side of the world.”

Lecture 1: Basics of dark energy Shinji Tsujikawa (Tokyo University of Science) ``Welcome to the dark side of the world.”
Science of the Dark Energy Survey Josh Frieman Fermilab and the University of Chicago Astronomy 41100 Lecture 1, Oct. 1 2010.

Science of the Dark Energy Survey Josh Frieman Fermilab and the University of Chicago Astronomy Lecture 1, Oct
1 What is the Dark Energy? David Spergel Princeton University.

1 What is the Dark Energy? David Spergel Princeton University.
Universe Eighth Edition Universe Roger A. Freedman William J. Kaufmann III CHAPTER 26 Cosmology Cosmology.

Universe Eighth Edition Universe Roger A. Freedman William J. Kaufmann III CHAPTER 26 Cosmology Cosmology.

Similar presentations

Ads by Google