Dark Matter distinguished by skewed microlensing in the "Dragon Arc"

TL;DR

This paper investigates the skewed distribution of microlensed stars along the Dragon Arc in galaxy cluster A370, proposing that wave dark matter ($$DM) explains the observed asymmetry better than CDM, with implications for dark matter particle mass.

Contribution

It introduces a novel interpretation of microlensing patterns as evidence for wave dark matter, contrasting with traditional CDM models, and predicts specific observational signatures.

Findings

Observed skewness of microlensed stars is consistent with wave dark matter predictions.

Wave dark matter explains the asymmetric band of microlenses better than CDM models.

Estimated boson mass of DM is ^{-22} eV, matching dwarf galaxy core estimates.

Abstract

Microlensed stars recently discovered by JWST & HST follow closely the winding critical curve of A370 along all sections of the ``Dragon Arc" traversed by the critical curve. These transients are fainter than $m_{AB}>26.5$, corresponding to the Asymptotic Giant Branch (AGB) and microlensed by diffuse cluster stars observed with $\simeq 18M_\odot/pc^2$, or about $\simeq 1$\% of the projected dark matter density. Most microlensed stars appear along the inner edge of the critical curve, following an asymmetric band of width $\simeq 4$kpc that is skewed by $-0.7\pm0.2$kpc. Some skewness is expected as the most magnified images should form along the inner edge of the critical curve with negative parity, but the predicted shift is small $\simeq -0.04$kpc and the band of predicted detections is narrow, $\simeq 1.4$kpc. Adding CDM-like dark halos of $10^{6-8}M_\odot$ broadens the band as desired but favours detections along the outer edge of the critical curve, in the wrong direction, where sub-halos generate local Einstein rings. Instead, the interference inherent to ``Wave Dark Matter" as a Bose-Einstein condensate ($\psi$DM) forms a symmetric band of critical curves that favours negative parity detections. A de Broglie wavelength of $\simeq 10$pc matches well the observed $4$kpc band of microlenses and predicts negative skewness $\simeq -0.6$kpc, similar to the data. The implied corresponding boson mass is $\simeq 10^{-22}$eV, in good agreement with estimates from dwarf galaxy cores when scaled by momentum. Further JWST imaging may reveal the pattern of critical curves by simply ``joining the dots" between microlensed stars, allowing wave corrugations of $\psi$DM to be distinguished from CDM sub-halos