Abstract
ABSTRACTGravitational lensing is a powerful tool for constraining substructure in the mass distribution of galaxies, be it from the presence of dark matter sub-haloes or due to physical mechanisms affecting the baryons throughout galaxy evolution. Such substructure is hard to model and is either ignored by traditional, smooth modelling, approaches, or treated as well-localized massive perturbers. In this work, we propose a deep learning approach to quantify the statistical properties of such perturbations directly from images, where only the extended lensed source features within a mask are considered, without the need of any lens modelling. Our training data consist of mock lensed images assuming perturbing Gaussian Random Fields permeating the smooth overall lens potential, and, for the first time, using images of real galaxies as the lensed source. We employ a novel deep neural network that can handle arbitrary uncertainty intervals associated with the training data set labels as input, provides probability distributions as output, and adopts a composite loss function. The method succeeds not only in accurately estimating the actual parameter values, but also reduces the predicted confidence intervals by 10 per cent in an unsupervised manner, i.e. without having access to the actual ground truth values. Our results are invariant to the inherent degeneracy between mass perturbations in the lens and complex brightness profiles for the source. Hence, we can quantitatively and robustly quantify the smoothness of the mass density of thousands of lenses, including confidence intervals, and provide a consistent ranking for follow-up science.
Highlights
Dark matter is a yet undetected component of the Universe, which does not emit light but participates via gravity in the collapse of matter to form galaxies and stars throughout its history (White & Rees 1978)
The phenomenon involves a distant galaxy-source and a closer galaxy-lens along the line of sight, which deflects the incoming light rays and forms multiple source images, arcs, and rings. By modelling these features one can assess the overall shape of the lens potential and its smoothness, which are directly linked to underlying dark matter properties and galaxy evolution/morphology [e.g. through composite lens potentials (Millon et al 2020), or higher order moments in the lens mass distribution (Hsueh et al 2017)]
The red rectangle is the uncertainty region encoded into the target distribution, which is the only information that our deep neural network (DNN) has access to as training labels
Summary
Dark matter is a yet undetected component of the Universe, which does not emit light but participates via gravity in the collapse of matter to form galaxies and stars throughout its history (White & Rees 1978). The phenomenon involves a distant galaxy-source and a closer galaxy-lens along the line of sight, which deflects the incoming light rays and forms multiple source images, arcs, and rings. By modelling these features one can assess the overall shape of the lens potential and its smoothness, which are directly linked to underlying dark matter properties (e.g. through the abundance of subhalos) and galaxy evolution/morphology [e.g. through composite lens potentials (Millon et al 2020), or higher order moments in the lens mass distribution (Hsueh et al 2017)]. The total mass distribution in massive elliptical galaxies has been found to be very close to isothermal (Koopmans et al 2006, 2009; Gavazzi et al 2007; Auger et al 2010; Barnabe et al 2011; Sonnenfeld et al 2013; Suyu et al 2014; Oldham & Auger 2018), and the presence of compact, massive, and dark substructures of the order of 108 M has been detected (Vegetti et al 2010, 2012; Fadely & Keeton 2012; MacLeod et al 2013; Nierenberg et al 2014; Li et al 2016; Hezaveh et al 2016; Birrer & Amara 2017)
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