Distinguishing between WDM and CDM by studying the gap power spectrum of stellar streams

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Distinguishing between WDM and CDM by studying the gap power spectrum of stellar streams based on arxiv:1804.04384, JCAP 07(2018)061 Nilanjan Banik Leiden University/GRAPPA, University of Amsterdam In collaboration with Gianfranco Bertone, Jo Bovy and Nassim Bozorgnia TeVPA 2018 Berlin, Germany

ΛCDM predicts many dark matter subhalos In the ΛCDM framework, hierarchical structure formation predicts a dark matter halo containing a Milky way sized galaxy should have hundreds of thousands of DM subhalos. Subhalos less massive than 10 9 Msun are devoid of stars and therefore remain undetected. Detecting these low mass subhalos will give crucial insight on the particle nature of dark matter. Lovell et al (2014) Dark matter can be broadly classified as cold and warm. WDM have higher velocity dispersion compared to CDM which prevents structure formation below a certain scale. CDM WDM

What are stellar streams? Gravitational potential of the Milky way galaxy can tidally disrupt near by globular clusters and dwarf galaxies stretching them along their orbit, resulting in a stream of stars stellar streams. Snapshots from animation done by Denis Erkal

Probing DM subhalos using stellar streams A cold stellar stream has largely a uniform stellar density along its length. A flyby DM subhalo will impart velocity kicks to the stars near the point of closest approach. This will put them in different orbits. This results in a region of low stellar density in the stellar stream or a gap. v M Credits Denis Erkal

We do see gaps in stellar streams! Price-Whelan and Bonaca (2018) GD-1 stream (Gaia + Pan-STARRS) And they are most probably caused by DM subhalo impacts 90% disk mass

The main idea CDM: many subhalos therefore more density perturbations (gaps) WDM: fewer subhalos therefore less density perturbations. Statistically, a stellar stream evolved in a WDM Universe should have less density perturbations than a one evolved in a CDM Universe.

Subhalo mass function of CDM and thermal WDM CDM : use from Aquarius simulations (Springel et al (2008)). The radial distribution of subhalos in the range 10 5 M - 10 9 M follows an Einasto profile. WDM : Lovell et al (2013) improved Schneider et al (2012) analytic fit: γ = 2.7, β = 0.99 Assume radial distribution also follows Einasto profile. M hm - half mode mass.

Simulating cold stellar streams Generation and evolution of a cold stellar stream is most easily described in frequency-angle space, where the stream is practically one dimensional. Their evolution is governed by these linear equations : Bovy (2014) Banik et al (2018) Koposov et al. (2010)

Modelling subhalo impacts in (Ω, θ) vs. N-body We model the stream-subhalo encounters by the impulse kick approximation. In (Ω, θ) space this translates to Bovy, Erkal, Sanders (2016) The stream simulations in the (Ω, θ) framework are orders of magnitude faster than in an N- body simulation, enabling us to run thousands of different subhalo realizations within a few hours. Density perturbation due to 24 subhalo impacts with masses between 10 6 M and 10 8 M create 5 visible gaps.

Density contrast

Power spectrum We compute the power of the density contrast along the stream. Median power of 2100 simulations This makes sense since higher the mass of thermal DM particle, closer it gets to CDM. Kennedy et al (2014)

Posterior PDFs We use the ABC (Approximate Bayesian Computation) method for parameter inference. Truth = 5 kev Truth = 1 GeV

Conclusions Stellar streams provide a novel method of detecting dark matter subhalos in our galaxy. We presented a statistical method of distinguishing between CDM and WDM by comparing the power of the density contrast of a stellar stream. By combining high quality data on several streams we will be able to put a more robust constraint on the mass of dark matter as well as be sensitive to subhalos with mass as low as 10 5 Msun. Detecting these subhalos will strongly suggest the existence of dark matter as well as give us valuable information on its particle nature.

END OF SLIDES

Reduction of subhalos Using APOSTLE simulations, Sawala et al (2016) found that baryonic effects such as interaction with the disk, can disrupt ~ 45 50 % of the dark matter subhalos.

We use the ABC (Approximate Bayesian Computation) method for parameter inference Likelihood free method. For a given set of data, which in our case is the computed power spectrum of a particular stream, we generated many simulations over a uniform prior [0.1-17] kev on the mass of WDM and accept only those that are within certain defined tolerance around the data summaries. From the accepted simulations, we construct the posterior.

Bode et al (2001), using P3M code, υ =1.12 (fitting parameter) The cutoff scale α depends only on the mass of the WDM particle This can be generalized to sterile neutrinos by including the lepton asymmetry parameter.

There is a bunch of stellar streams to that we know till date. GD-1 and Pal 5 are two of the most well studied globular cluster streams.

Backup slides

Extreme cases Upper 2σ 3.3 kev Upper 2σ 5 kev Lower 2σ 1 GeV

No subhalo impacts

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