In the cold dark matter (CDM) paradigm, an association between the hypothetic dark matter (DM) and its stellar counterpart is
expected.
However, parametric strong-lensing studies of galaxy clusters often display misleading features: DM components on the group or cluster scale
without any stellar counterpart, offsets between the two components that are larger
than what might be allowed by CDM or self-interacting DM models,
or significant unexplained external shear components.
This is the case in the galaxy cluster Abell 370, whose mass distribution has been the subject of several studies that were
motivated by a wealth of data.
The cluster was described parametrically with strong-lensing techniques by a model with four dark matter clumps and
galaxy-scale perturbers, and with a significant external shear
component, whose physical origin remains a challenge.
The dark matter distribution features a mass clump without a stellar counterpart and a significant offset between one of the dark matter clumps and
its associated stellar counterpart.
This paper is based on buffalo data, and we begin by revisiting this mass model.
Sampling this complex parameter space with Markov chain Monte Carlo (MCMC) techniques, we find a solution that does not require any
external shear and provides a slightly better root mean square (RMS) than previous
models (0.7arcsec compared to 0.9arcsec ).
Investigating this new solution further, in particular, by varying the parameters that lead the mcmc sampler, we present a class of models that can accurately reproduce the
strong-lensing data,
but whose parameters for the dark matter component are poorly constrained. This limits any insights into its
properties.
We then developed a model in which each large-scale dark matter component must be associated with a
stellar counterpart.
This model with three dark matter clumps cannot reproduce the observational constraints
with an rms smaller than 2.3arcsec , and the parameters describing this dark matter component remain
poorly constrained.
Examining the total projected mass maps, we find a good agreement between the total mass and the stellar
distribution, which are both bimodal to first order.
We interpret the misleading features of the mass model with four dark matter clumps and the failure of the mass model with three
dark matter clumps as being symptomatic of the lacking realism of a parametric description
of the dark matter distribution in such a complex merging cluster. We encourage caution and attention on the
outputs of parametric strong-lensing modelling.
We briefly discuss the implications of our results for using Abell 370 as a
gravitational telescope. With the class of models that reproduce the strong-
lensing data, we computed the magnifications for background Lyalpha emitters,
and we present the critical curves obtained for the redshift of the
Dragon arc, whose recent observations with the James Webb Space Telescope prompted interest.
Finally, in light of our results, we discuss the strategy of choosing merging (multi-modal) clusters as gravitational telescopes
compared to simple (unimodal) clusters.
