I have moved on to the University of Helsinki. My blog is continued here. Nähdään Helsingissä!
From January 14-17, Oslo’s famous Holmenkollen played a fitting backdrop to the remarkable Beyond LCDM conference, an assembly of cosmologists from all over the world, working within and without the so-called standard model.
For those of us who have learned to refer to LCDM as the “standard model” of cosmology, it gave an insight into the range of alternatives out there, while those in the community hoping to slay the LCDM dragon were reminded that, outrageous and ugly as it may seem, LCDM continues to be notoriously tough to beat with observational evidence.
Dirac Day is being held in Durham, and I have prepared another augmented reality poster using DARO (This time exploring the state container, which allows for much greater flexibility). As before, the augmented reality elements will work if the poster is viewed on your screen just like the printed poster.
If you have just scanned the QR code using your phone, but you are reading this message, you probably have not installed the DARO viewer yet. Please speak to me – I’ll be happy to lend you my tablet. Alternatively, you can download the latest version of DARO for your phone from the DARO project website. I can also help you install it.
DARO is being developed in Durham by Jascha Schewtschenko. If you are interested, please contact him via the DARO website.
If you have just scanned the QR code using your phone, but you are reading this message, you probably have not installed the DARO viewer yet. Please speak to me at the IAU meeting – I’ll be happy to lend you my tablet. Alternatively, you can download the latest version of DARO for your phone from the DARO project website:
DARO is developed by Jascha Schewtschenko at Durham University. By downloading and installing DARO, you agree to its license. In the future, please always visit the project website for the latest version.
We have just written a new paper, where we study the impact of reionization on galaxy formation in the Local Group using computer simulations.
We find that most of the dark matter halos of similar mass to the observed dwarf galaxies are in fact completely dark; unable to form stars after reionization heats up the intergalactic gas. Those halos that do form stars are not only rare, but also special: they formed much earlier than “typical” halos, and if they are satellites, they follow different orbits than a pure dark matter simulation would predict. We conclude that if we want to understand dark matter by only studying the halos that host the observable galaxies, we have to be aware that we are dealing with a very special selection. We call them The Chosen Few.
From Fig. 1: Gas density in the Local Group simulation with reionization (left) and without reionization (right). Without reionization, many more “clumps” of gas can cool and form dwarf galaxies, but with reionization included, only a small fraction of low-mass halos keep enough cold gas for star formation, leaving most dark matter halos completely dark.
Our paper “The chosen few: the low mass halos that host faint galaxies” has been in the news!
- The Daily Mail Online: Are we on the brink of finding dark matter?
- Phys.org: ‘Cosmic own goal’ another clue in hunt for dark matter
- Motherboard.vice.com: Dark Matter Halos are Sad Would-Be Galaxies
- Red Orbit: In the Hunt For Dark Matter, New Simulations Show Evolution Of “Local Universe”
- ANI News: Understanding formation of galaxies could solve mystery of dark matter
- Science World Report: Supercomputer Simulations Chart the Evolution of the Local Universe
- Science 2.0: Just In Time For The World Cup, The Cosmos Scores A Dark Matter Own Goal
- Astronomie.nl: Eerste sterren hinderden de vorming van sterrenstelsels
- Tendencias 21: Nuevos descubrimientos nos acercan a la materia oscura
- INAF: Aloni sterili e materia oscura
In this paper, we look at how the appearance of dark halos that have failed to form galaxies changes the relation between galaxies and dark matter halos.
Abundance matching is a very neat method of statistically linking (simulated) dark matter halos to (observed). It requires no detailed knowledge about galaxy formation physics and just assumes that each halo contains exactly one galaxy, with brighter galaxies living in more massive halos. From these simple assumptions, one can derive average the stellar mass – halo mass relation for all galaxies.
It had been argued (including by myself) that the average relation inferred from abundance matching does not match the values measured for individual dwarf galaxies, whether by observations or direct simulations. This has been interpreted as a problem for the LCDM model, which seemed to produce too many halos. However, what we show in our new paper is that the simple assumption of one galaxy per halo breaks down for low mass halos, because many of them do not host a galaxy at all. We find that once these “dark” halos and other baryonic effects are taken into account, the stellar-halo mass relation bends upwards and matches the observations.
From Fig. 4: The classic abundance matching relation (black line) does not match the data (squares and triangles) at the low mass end. However, after the relation gets bent by baryons (red line), the disagreement is resolved.
If you’d like to read more, please take a look at our paper.
Collaborators: Carlos S. Frenk, Azadeh Fattahi, Julio F. Navarro, Richard G. Bower, Robert A. Crain, Claudio Dalla Vecchia, Michelle Furlong, Adrian Jenkins, Ian G. McCarthy, Yan Qu, Matthieu Schaller, Joop Schaye, Tom Theuns