%0 Generic %1 nierenberg2016missing %A Nierenberg, A. M. %A Treu, T. %A Menci, N. %A Lu, Y. %A Torrey, Paul %A Vogelsberger, M. %D 2016 %K missing problem satellite %T The Missing Satellite Problem in 3D %U http://arxiv.org/abs/1603.01614 %X It is widely believed that the large discrepancy between the observed number of satellite galaxies and the predicted number of dark subhalos can be resolved via a variety of baryonic effects which suppress star formation in low mass halos.Supporting this hypothesis, numerous high resolution simulations with star formation, and associated feedback have been shown to reproduce the satellite luminosity function around Milky Way-mass simulated galaxies at redshift zero. However, a more stringent test of these models is their ability to simultaneously match the satellite luminosity functions of a range of host halo masses and redshifts. In this work we measure the luminosity function of faint (sub-Small Magellanic Cloud luminosity) satellites around hosts with stellar masses 10.5$<łog_10$M$_*$/M$_ødot<11.5$ to an unprecedented redshift of 1.5. This new measurement of the satellite luminosity function provides powerful new constraining power; we compare these results with predictions from four different simulations and show that although the models perform similarly over-all, no one model reproduces the satellite luminosity function reliably at all redshifts and host stellar masses. This result highlights the continued need for improvement in understanding the fundamental physics that governs satellite galaxy evolution.

@misc{nierenberg2016missing, abstract = {It is widely believed that the large discrepancy between the observed number of satellite galaxies and the predicted number of dark subhalos can be resolved via a variety of baryonic effects which suppress star formation in low mass halos.Supporting this hypothesis, numerous high resolution simulations with star formation, and associated feedback have been shown to reproduce the satellite luminosity function around Milky Way-mass simulated galaxies at redshift zero. However, a more stringent test of these models is their ability to simultaneously match the satellite luminosity functions of a range of host halo masses and redshifts. In this work we measure the luminosity function of faint (sub-Small Magellanic Cloud luminosity) satellites around hosts with stellar masses 10.5$<\log_{10}$M$_*$/M$_\odot<11.5$ to an unprecedented redshift of 1.5. This new measurement of the satellite luminosity function provides powerful new constraining power; we compare these results with predictions from four different simulations and show that although the models perform similarly over-all, no one model reproduces the satellite luminosity function reliably at all redshifts and host stellar masses. This result highlights the continued need for improvement in understanding the fundamental physics that governs satellite galaxy evolution.}, added-at = {2016-03-08T09:41:57.000+0100}, author = {Nierenberg, A. M. and Treu, T. and Menci, N. and Lu, Y. and Torrey, Paul and Vogelsberger, M.}, biburl = {https://www.bibsonomy.org/bibtex/2f420447114a5c4d6b1f7828dcb397d58/miki}, description = {[1603.01614] The Missing Satellite Problem in 3D}, interhash = {4eb45245adc2da5f7df7ebfc37a9b591}, intrahash = {f420447114a5c4d6b1f7828dcb397d58}, keywords = {missing problem satellite}, note = {cite arxiv:1603.01614Comment: 9 pages, 2 figures, submitted to MNRAS}, timestamp = {2016-03-08T09:41:57.000+0100}, title = {The Missing Satellite Problem in 3D}, url = {http://arxiv.org/abs/1603.01614}, year = 2016 }