The collision of two vast galaxy clusters, including El Gordo, challenges the predictions of the Lambda-cold dark matter (ΛCDM) cosmological model, suggesting a need to reassess our understanding of cosmic structure formation.
A collision of two massive clusters of galaxies when the Universe was half its current age should not have happened according to the standard theory of cosmology, says a new study by an international group of astronomers.
The El Gordo Cluster
According to the Lambda-cold dark matter (ΛCDM) standard model of cosmology, galaxies form first and only later combine into larger clusters of galaxies. Thus, galaxy clusters should take a lot of time to appear on the cosmic scene. The new study, published in the Astrophysical Journal, challenges this by showing that two extremely large galaxy clusters collided at a very high speed when the Universe was only about half its current age.
The cluster pair in question is known as El Gordo – which means “The Fat One” in Spanish – an apt name given its mass is about 2000 trillion times that of the Sun (2 followed by fifteen zeroes). The new study uses an updated estimate of its mass that is much more precise. This removes a major source of uncertainty in an earlier study by the same authors about just how problematic El Gordo is for ΛCDM.
Composite color image of the interacting galaxy cluster El Gordo, showing X-ray light from NASA’s Chandra X-ray Observatory in blue, optical data from the European Southern Observatory’s Very Large Telescope in red, green, and blue, and infrared emission from NASA’s Spitzer Space Telescope in red and orange. Credit: X-ray: NASA/CXC/Rutgers/J.Hughes et al, Optical: ESO/VLT/Pontificia Universidad. Catolica de Chile/L.Infante & SOAR (MSU/NOAO/UNC/CNPq-Brazil)/Rutgers/F.Menanteau, IR: NASA/JPL/Rutgers/F.Menanteau
The mass was estimated using the deflection of light from background galaxies, whose shape appears distorted thanks to the gravitational pull from El Gordo – a bit like a magnifying glass. This ‘weak lensing’ mass was obtained using the Hubble Space Telescope, but agrees with more recent results from the James Webb Space Telescope and other studies using other methods. The mass now has a modest 10% uncertainty.
Analyzing the Collision
The research, led by Elena Asencio, a PhD student at the University of Bonn, used previously published detailed simulations of the interaction to estimate the speed at which the clusters collided. The authors then searched through a less detailed cosmological ΛCDM simulation covering a very large volume to look for simulated cluster pairs. The aim was to count how many of these are broadly analogous to what El Gordo was like shortly before the collision. This was done with an innovative “lightcone tomography” method which considers that more distant objects are viewed further back in time, when there was less structure.
The results revealed that the tension with ΛCDM is very severe for any plausible collision velocity. Moreover, the remaining uncertainty in El Gordo’s mass no longer plays a significant role.
Elena said: “The results of our previous study were questioned by some scientists once an updated mass estimate for El Gordo was published and came in slightly lower. This does reduce the tension with ΛCDM, but it is still highly significant for any plausible collision velocity. Hundreds of detailed simulations show that El Gordo cannot look like the photos with a much slower collision velocity that could plausibly arise in ΛCDM.”
While it is possible to get a simulation that looks like El Gordo with a more rapid collision, such an event is too rare in ΛCDM. This is because it would be very unusual to find two such massive clusters within striking distance at such an early stage in cosmic history. Further requiring them to be headed towards each other at a high speed stretches credibility. The new study and the more precise mass measurement may lead to more efforts to simulate El Gordo to better understand this enigmatic object.
Beyond El Gordo
El Gordo is not the only example of a cluster collision at odds with ΛCDM. Dr. Indranil Banik of the School of Physics and Astronomy at St Andrews, who developed the statistical analysis used in this project, said: “The Bullet Cluster is another example of a highly energetic collision between two galaxy clusters, albeit at a later epoch. Taken in combination with El Gordo, the situation becomes even worse for ΛCDM. And several other examples are known and mentioned in our study.”
There are also several studies showing that individual galaxies seem to form much more rapidly than expected in ΛCDM, largely thanks to very recent James Webb data. Of the broader context of the El Gordo results, Pavel Kroupa, Professor at the University of Bonn and Charles University in Prague, said: “There is now a lot of evidence that structure formation in the Universe occurred faster than expected in ΛCDM. We are currently exploring other lines of evidence for this.”
Reference: “The El Gordo Galaxy Cluster Challenges ΛCDM for Any Plausible Collision Velocity” by Elena Asencio, Indranil Banik and Pavel Kroupa, 4 September 2023, Astrophysical Journal.
DOI: 10.3847/1538-4357/ace62a
Or, maybe the true age of the universe is almost twice the “standard model” value, as recent peer-reviewed papers have hypothesized. I believe this is linked to MOND gravity theories. If that turns out to be true, then it would also get rid of the troublesome notion of cosmic inflation in the early universe, which has always struck me as a huge kludge in our cosmology models. Kind of like the web meme:
1. Gather data about the universe.
2. Build a standard model of how it happened.
3. Find a big problem with how it could have become so big in its estimated age.
4. ???
5. Profit!!
Am a bit naive. If the universe is expanding evenly and the space between galaxies increasing, how come galaxies can collide?