Constraining the Energy Density of the Universe Using Type 1a Supernovae as Standard Candles

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Constraining the Energy Density of the Universe Using Type 1a Supernovae as Standard Candles Rene N. Ortman rortman@fit.edu Florida Institute of Technology Advisor: Dr. Terry Walker OSU REU 99 Supported by the NSF Final Paper August 20, 1999 Abstract Taking data from the Supernova Cosmology group at Berkley, we are able to expand their project to three dimensions by adding a radiation parameter to the total energy density of the universe. Using type 1a Supernova as standard candles (objects of known absolute magnitude), we are able to calculate their luminosity distance and hence, a value for the deceleration parameter (q o ). Doing a χ 2 contour plot of q o as a function of the parameters of the energy density, omega matter (Ω m ), omega radiation (Ω r ), and omega vacuum (Ω Λ ), we get a best fit to our data. Unlike both the Supernova Cosmology Group and last year s candidate, Jason Farris, we are not constraining Ω o 1 to be unity (a flat universe). We ended up with several models that are a good fit to the standard model of the universe. 1 The quantity Ω o ρ o /ρ c, where ρ o is the present mass density of the Universe, and ρ c is the critical density, ρ c 3H o 2 /8πG = 1.88 10-29h2gcm-3

2 1 Background Cosmology 1.1 Type 1a Supernova Type 1a Supernova occur in binary star systems involving a main sequence star and a white dwarf, the end product of a main sequence star. The white dwarf is smaller in size, but is more dense and therefore more massive than the main sequence star. The white dwarf will pull material from its orbiting companion until it reaches it s critical mass, known as the Chandrasehkar Limit; at which point the dwarf violently explodes as a supernova. Type 1a Supernova are characterized by the presence of silicon lines in their spectra. 1.2 Standard Candles A standard candle is a very useful class of objects in which there is a certain intrinsic brightness that links them all together; or in other words, once the luminosity of one nearby standard candle is known, the luminosity of all the other members of the same class is known. From this known luminosity, we can easily calculate the distance to these objects, which is quite possibly the most difficult variable to determine in astronomy today. 1.3 Ω o = 1 We observe, at least the matter portion of the energy density of the universe, to be nearly one, Ω m 0.3±0.1. This implies that at the beginning of the universe, Ω o must have been even closer to one. Imagine that for every Plank time frame (5.4 10-44 sec), Ω o changed so that it moved further away from its original value. If that original value had not been almost exactly one, Ω o today would not be only one order of magnitude off from one.

3 1.4 Ωr < 0.3 Radiation scales as (1 + z) 4 while matter scales as (1 + z) 3. As we increase redshift 2, or go back in time 3, radiation quickly takes over the matter-dominated universe that we live in today. If Ω r is above 0.3, then this critical changing point is pushed forward in time and the universe as we know it would not have sufficient time to coalesce into the galaxy formations we see today. 2 Calculating Distance High-z SNe 1a data is shown to the right where µ o is given in units of distance moduli. The conversion to luminosity distance (D 4 L ) in Megaparsecs is: µ o = m-m = 5log(D L ) + 25 (1) From here, we can expand out the luminosity distance in terms of the Hubble 5 constant (H o ), redshift (z), and the deceleration parameter (q o ): D L = H -1 o z + H -1 o z 2 ((1-q o )/2) (2) The Hubble constant is difficult to pinpoint due to parametric dependence on cosmological parameters at high redshift, but at modest redshift (z 1), one may determine H o : on a log z vs. log D L, log H o is the interception on the log z axis. The most recent value of H o is 70±7 km/s/mpc. 2 z = redshift, according to the Doppler Effect, the spectrum of an object moving away from a reference point will be shifted towards the red end. 3 The further objects are from Earth, the more redshifted they seem to be. Also, the further away these objects are, the earlier they must have formed since the universe has been continually expanding. Therefore, increasing redshift is like looking back in time at an earlier universe. 4 D 2 L Λ/4πΦ Since space has expanded by the time we detect the light from a distant object, the expansion of the universe requires the specific luminosity distance definition.

4 Note: In our attempt to calculate q o using a best fit technique, the values we generated were unpleasant. Further attempts were abandoned and the values from Jason Farris paper, q o = -0.5±0.2, and the High-z Supernova Research Team, q o = -1±0.4, were used. Some Constraints We used several constraints in our analysis in order to determine which Universes could be probable: Ω m 0.3 Ω r 0 for Ω o = 1, Ω Λ 0.7 3 Data Fig. 1 The projection onto the Ω m, Ω r plane. This was done in order to compare the results of the Supernova Cosmology Group with our own. 5 H o is the present expansion rate of the Universe.

Fig. 2 Shows the results of the Supernova Cosmology Group where Ω r = 0. As you can see, the best fit for the Universe is a flat Universe (Ω o = 1) with a deceleration parameter (q o ) = -0.5. 5

6 Fig. 3 Shows a three dimensional plot of the components of the total energy density of the universe. Here we see the best q o value of 0.5 in red with 1 sigma planes in blue, the best Ω m value of 0.3 in green with 1 sigma planes in dark purple, a constraint where Ω Λ 0.7, and an, open, flat, and closed universe in light purple, orange, and light purple respectively moving front to back.

7 Fig. 4 - (above) The results of last year s REU student, Jason Farris. The blue line represents a best fit to the data while the green lines are the one sigma level. The red line represents the boundary at which Ωm is allowed: Ω m 0.2. Fig. 5 (above) Here we have a replica of Farris plot: a flat Universe with a deceleration of 0.5. The best fit line (blue) intersects both axes at slightly different values, but this is mostly due to the different methods used to produce these results. As you can see, this is a probable solution in which it is possible to have Ω m 0.3 with Ω r 0 and a positive Ω Λ component. Fig. 6 & 7 (above) Here we have a flat Universe and an open Universe where the best fit lines (blue) leads to negative values for Ω m and Ω r, hence, not very probable solutions. There is, however, a very small portion in the red zones (the valley area) where Ω m and Ω r are positive, but this leads to an Ω m value of less than 0.3. We already observe Ω m 0.3, so consequently we can rule out these solutions.

8 Fig. 8 (above) Here we have an open Universe where the best fit line (blue)leads to negative values for Ω m and Ω r, hence, not a very probable solution. Fig. 9 (above) Here is a theoretically probable solution according to the Ω m 0.3 constraint, however, there could be an upper limit to Ω m that restricts the graph that we do not know about yet. Fig. 10 (left) Here is a very probable result for a closed Universe. For Ω m 0.3, we get a value positive or zero value for Ω r, and a positive value for Ω Λ

9 References [1] Edward W. Kolb and Michael S. Turner. The Early Universe. Addison-Wesley Publishing Co., 1990 [2] J. D. Cohn. Living with Lambda. astro-ph/9807128, 13 Jul 1998. [3] Jason L. Farris. Constraining Cosmological Parameters Using Type 1a Supernova as Standard Candles. [4] The Supernova Cosmology Project. Scheduled Discoveries of 7+ High-Redshift Supernovae: First Cosmology Results and bounds on q o. astro-ph/9602122, 22 Feb 1996. [5] S. Perlmutter, et. al. A Supernova at z = 0.458 and Implications for measuring the Cosmological Deceleration. astro-ph/9505023, 4 May 95. [6] Adam G. Reiss, et. al. Observational Evidence from Supernova for an Accelerating Universe and a Cosmological Constant. astro-ph/9805201, 15 May 1998. [7] Alexei V. Filippenko and Adam G. Reiss. Results from the High-z Supernova Search Team. astro-ph/9807008, 1 July 1998. Thanks I d like to first thank my advisor Dr. Terry Walker and his substitute Dr. Robert Scherrer for their guidance and support. Many thanks to Dr. Palmer and Dr. Linn Van Woerkom for their wonderful group leadership and activity planning and basically for putting up with all sixteen of us for ten whole weeks! I would also like to thank Dr. Gregg Kilcup for his patience and understanding when I desperately needed help learning Mathematica. And a special thanks to Ohio State and to the NSF for making this all possible

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