PUBLISHED.rst

Published work with lenstronomy

In this section you can find the concept papers lenstronomy is based on and a list of science publications that made use of lenstronomy before 09/2022. For a more complete and current list of publications using lenstronomy we refer to the NASA/ADS query (this incudes all publications citing lenstronomy papers, which is not the same as publications making active use of the software).

Core lenstronomy methodology and software publications

• lenstronomy: Multi-purpose gravitational lens modelling software package; Birrer & Amara 2018

  This is the lenstronomy software paper. Please cite this paper whenever you make use of lenstronomy. The paper gives a design overview and highlights some use cases.

• lenstronomy II: A gravitational lensing software ecosystem; Birrer et al. 2021

  JOSS software publication. Please cite this paper whenever you make use of lenstronomy.

• Gravitational Lens Modeling with Basis Sets; Birrer et al. 2015

  This is the method paper lenstronomy is primary based on. Please cite this paper whenever you publish results with lenstronomy by using Shapelet basis sets and/or the PSO and MCMC chain.

Related software publications

• A versatile tool for cluster lensing source reconstruction. I. methodology and illustration on sources in the Hubble Frontier Field Cluster MACS J0717.5+3745; Yang et al. 2020a

  reconstructing the intrinsic size-mass relation of strongly lensed sources in clusters

• SLITronomy: towards a fully wavelet-based strong lensing inversion technique; Galan et al. 2020

  This is the method paper presenting SLITromomy, an improved version of the SLIT algorithm fully implemented and compatible with lenstronomy.

• deeplenstronomy: A dataset simulation package for strong gravitational lensing; Morgan et al. 2021a

  Software to simulating large datasets for applying deep learning to strong gravitational lensing.

• Galaxy shapes of Light (GaLight): a 2D modeling of galaxy images; Ding et al. 2021b

  Tool to perform two-dimensional model fitting of optical and near-infrared images to characterize surface brightness distributions.

• LensingETC: a tool to optimize multi-filter imaging campaigns of galaxy-scale strong lensing systems; Shajib et al. 2022b

  A Python package to select an optimal observing strategy for multi-filter imaging campaigns of strong lensing systems.

• Using wavelets to capture deviations from smoothness in galaxy-scale strong lenses; Galan et al. 2022

  Presenting a new software 'herculens'. The code structure and part of the modeling routines of herculens are based on lenstronomy.

Scientific publication before 09/2022

Measuring the Hubble constant

• The mass-sheet degeneracy and time-delay cosmography: analysis of the strong lens RXJ1131-1231; Birrer et al. 2016

  This paper performs a cosmographic analysis and applies the Shapelet basis set scaling to marginalize over a major lensing degeneracy.

• H0LiCOW - IX. Cosmographic analysis of the doubly imaged quasar SDSS 1206+4332 and a new measurement of the Hubble constant; Birrer et al. 2019

  This paper performs a cosmographic analysis with power-law and composite models and covers a range in complexity in the source reconstruction

• Astrometric requirements for strong lensing time-delay cosmography; Birrer & Treu 2019

  Derives requirements on how well the image positions of time-variable sources has to be known to perform a time-delay cosmographic measurement

• H0LiCOW XIII. A 2.4% measurement of H0 from lensed quasars: 5.3σ tension between early and late-Universe probes; Wong et al. 2019

  Joint analysis of the six H0LiCOW lenses including the lenstronomy analysis of J1206

• STRIDES: A 3.9 per cent measurement of the Hubble constant from the strongly lensed system DES J0408-5354; Shajib et al. 2019

  most precise single lensing constraint on the Hubble constant. This analysis includes two source planes and three lensing planes

• TDCOSMO. I. An exploration of systematic uncertainties in the inference of H0 from time-delay cosmography Millon et al. 2020

  mock lenses to test accuracy on the recovered H0 value

• Lens modelling of the strongly lensed Type Ia supernova iPTF16geu Moertsell et al. 2020

  Modeling of a lensed supernova to measure the Hubble constant

• The impact of line-of-sight structures on measuring H0 with strong lensing time-delays Li, Becker and Dye 2020

  Point source position and time-delay modeling of quads

• TDCOSMO III: Dark matter substructure meets dark energy -- the effects of (sub)halos on strong-lensing measurements of H0 Gilman, Birrer and Treu 2020

  Full line-of-sight halo rendering and time-delay analysis on mock images

• TDCOSMO IV: Hierarchical time-delay cosmography -- joint inference of the Hubble constant and galaxy density profiles Birrer et al. 2020

  lenstronomy.Galkin for kinematics calculation that folds in the hierarchical analysis

• TDCOSMO V: strategies for precise and accurate measurements of the Hubble constant with strong lensing Birrer & Treu 2020

  lenstronomy.Galkin for kinematics calculation that folds in the hierarchical analysis for a forecast for future Hubble constant constraints

• Large-Scale Gravitational Lens Modeling with Bayesian Neural Networks for Accurate and Precise Inference of the Hubble Constant Park et al. 2020

  BBN lens model inference using lenstronomy through `baobab <https://github.com/jiwoncpark/baobab>`_ for training set generation.

• Improved time-delay lens modelling and H0 inference with transient sources Ding et al. 2021a

  Simulations and models with and without lensed point sources to perform a time-delay cosmography analysis.

• Gravitational lensing H0 tension from ultralight axion galactic cores Blum & Teodori 2021

  Investigating the detectability of a cored component with mock imaging modeling and comparison of kinematic modeling.

• The Hubble constant from strongly lensed supernovae with standardizable magnifications Birrer, Dhawan, Shajib 2021

  Methodology and forecast to use standardizable magnifications to break the mass-sheet degeneracy and hierarchically measure H0.

• AI-driven spatio-temporal engine for finding gravitationally lensed supernovae Ramanah et al. 2021

  Simulated images with time series of lensed supernovae.

• Systematic errors induced by the elliptical power-law model in galaxy-galaxy strong lens modeling Cao et al. 2021

  Computing lensing quantities from mass maps.

• TDCOSMO. VII. Boxyness/discyness in lensing galaxies : Detectability and impact on H0 Van de Vyvere et al. 2021

  Assessment of boxy and discy lens model on the inference of H0.

• TDCOSMO. IX. Systematic comparison between lens modelling software programs: time delay prediction for WGD 2038−4008 Shajib et al. 2022a

  modeling of a time-delay lens and comprehensive analysis between two modeling codes.

• Forecast of observing time delay of the strongly lensed quasars with Muztagh-Ata 1.93m telescope Zhu et al. 2022a

  Using lenstronomy to reproduce a lens and simulate the observed images based on parameters fitted by other work.

• Consequences of the lack of azimuthal freedom in the modeling of lensing galaxies van de Vyvere et al. 2022

  Implemented a model ’ElliSLICE’ to describe radial changes in ellipticities and investigating assumptiosn on azimuthal freedom in the reconstruction.

Dark Matter substructure

• Lensing substructure quantification in RXJ1131-1231: a 2 keV lower bound on dark matter thermal relic mass; Birrer et al. 2017b

  This paper quantifies the substructure content of a lens by a sub-clump scanning procedure and the application of Approximate Bayesian Computing.

• Probing the nature of dark matter by forward modelling flux ratios in strong gravitational lenses; Gilman et al. 2018

• Probing dark matter structure down to 10**7 solar masses: flux ratio statistics in gravitational lenses with line-of-sight haloes; Gilman et al. 2019a

• Double dark matter vision: twice the number of compact-source lenses with narrow-line lensing and the WFC3 Grism; Nierenberg et al. 2019

• Warm dark matter chills out: constraints on the halo mass function and the free-streaming length of dark matter with 8 quadruple-image strong gravitational lenses; Gilman et al. 2019b

• Constraints on the mass-concentration relation of cold dark matter halos with 11 strong gravitational lenses; Gilman et al. 2019c

• Circumventing Lens Modeling to Detect Dark Matter Substructure in Strong Lens Images with Convolutional Neural Networks; Diaz Rivero & Dvorkin

• Dark Matter Subhalos, Strong Lensing and Machine Learning; Varma, Fairbairn, Figueroa

• Quantifying the Line-of-Sight Halo Contribution to the Dark Matter Convergence Power Spectrum from Strong Gravitational Lenses; Sengul et al. 2020

• Detecting Subhalos in Strong Gravitational Lens Images with Image Segmentation; Ostdiek et al. 2020a

• Extracting the Subhalo Mass Function from Strong Lens Images with Image Segmentation; Ostdiek et al. 2020b

• Strong lensing signatures of self-interacting dark matter in low-mass halos; Gilman et al. 2021a

• Substructure Detection Reanalyzed: Dark Perturber shown to be a Line-of-Sight Halo; Sengul et al. 2021

  modeling a line-of-sight mini-halo

• The primordial matter power spectrum on sub-galactic scales; Gilman et al. 2021b

  rendering sub- and line-of-sight halos

• From Images to Dark Matter: End-To-End Inference of Substructure From Hundreds of Strong Gravitational Lenses; Wagner-Carena et al. 2022

  rendering sub- and line-of-sight halos and generating realistic training sets of images for substructure quantifications

• Interlopers speak out: Studying the dark universe using small-scale lensing anisotropies; Dhanasingham et al. 2022

  rendering line of sight and subhalos with pyhalo on top of lenstronomy

• Probing Dark Matter with Strong Gravitational Lensing through an Effective Density Slope; Senguel & Dvorkin 2022

  measuring an effective slope of a subhalo in HST data and tests on mock data from N-body simulations

• Quantum fluctuations masquerade as halos: Bounds on ultra-light dark matter from quadruply-imaged quasars; Laroche et al. 2022

  using lenstronomy for flux ratio statistics calculation with pyHalo

• Constraining resonant dark matter self-interactions with strong gravitational lenses; Gilman et al. 2022

  using lenstronomy for flux ratio statistics calculation with pyHalo

Lens searches

• Strong lens systems search in the Dark Energy Survey using Convolutional Neural Networks; Rojas et al. 2021

  simulating training sets for lens searches

• On machine learning search for gravitational lenses; Khachatryan 2021

  simulating training sets for lens searches

• DeepZipper: A Novel Deep Learning Architecture for Lensed Supernovae Identification; Morgan et al. 2021b

  Using deeplenstronomy to simulate lensed supernovae data sets

• Detecting gravitational lenses using machine learning: exploring interpretability and sensitivity to rare lensing configurations; Wilde et al. 2021b

  Simulating compound lenses

• DeepZipper II: Searching for Lensed Supernovae in Dark Energy Survey Data with Deep Learning; Morgan et al. 2022

  Using deeplenstronomy to simulate lensed supernovae training sets

• DeepGraviLens: a Multi-Modal Architecture for Classifying Gravitational Lensing Data; Oreste Pinciroli Vago et al. 2022

  Using deeplenstronomy to simulate lensed supernovae training sets

Galaxy formation and evolution

• Massive elliptical galaxies at z∼0.2 are well described by stars and a Navarro-Frenk-White dark matter halo; Shajib et al. 2020a

  Automatized modeling of 23 SLACS lenses with dolphin, a lenstronomy wrapper

• High-resolution imaging follow-up of doubly imaged quasars; Shajib et al. 2020b

  Modeling of doubly lensed quasars from Keck Adaptive Optics data

• The evolution of the size-mass relation at z=1-3 derived from the complete Hubble Frontier Fields data set; Yang et al. 2020b

  reconstructing the intrinsic size-mass relation of strongly lensed sources in clusters

• PS J1721+8842: A gravitationally lensed dual AGN system at redshift 2.37 with two radio components; Mangat et al. 2021

  Imaging modeling of a dual lensed AGN with point sources and extended surface brightness

• RELICS: Small Lensed z≥5.5 Galaxies Selected as Potential Lyman Continuum Leakers; Neufeld et al. 2021

  size measurements of high-z lensed galaxies

• The size-luminosity relation of lensed galaxies at z=6−9 in the Hubble Frontier Fields; Yang et al. 2022a

  size measurements of high-z lensed galaxies

• The Near Infrared Imager and Slitless Spectrograph for the James Webb Space Telescope -- II. Wide Field Slitless Spectroscopy; Willott et al. 2022

  lensing calculations in cluster environments

• Inferences on relations between distant supermassive black holes and their hosts complemented by the galaxy fundamental plane; Silverman et al. 2022

  galaxy size measurement with quasar decomposition

• Concordance between observations and simulations in the evolution of the mass relation between supermassive black holes and their host galaxies; Ding et al. 2022

  galaxy size measurement with quasar decomposition

• Early results from GLASS-JWST. V: the first rest-frame optical size-luminosity relation of galaxies at z>7; Yang et al. 2022b

  galaxy size measurement from JWST data with Galight/lenstronomy

• A New Polar Ring Galaxy Discovered in the COSMOS Field; Nishimura et al. 2022
• Webb's PEARLS: dust attenuation and gravitational lensing in the backlit-galaxy system VV 191; Keel et al. 2022

Automatized Lens Modeling

• Is every strong lens model unhappy in its own way? Uniform modelling of a sample of 12 quadruply+ imaged quasars; Shajib et al. 2018

  This work presents a uniform modelling framework to model 13 quadruply lensed quasars in three HST bands.

• Hierarchical Inference With Bayesian Neural Networks: An Application to Strong Gravitational Lensing; Wagner-Carena et al. 2020

  This work conducts hierarchical inference of strongly-lensed systems with Bayesian neural networks.

• A search for galaxy-scale strong gravitational lenses in the Ultraviolet Near Infrared Optical Northern Survey (UNIONS); Savary et al. 2021

  Automated modeling of best candidates of ground based data.

• GIGA-Lens: Fast Bayesian Inference for Strong Gravitational Lens Modeling; Gu et al. 2022

  lenstronomy-inspired GPU lensing code with PEMD+shear and Sersic modeling, and tested against lenstronomy.

• STRIDES: Automated uniform models for 30 quadruply imaged quasars; Schmidt et al. 2022

  Automated and uniform modeling of 30 quadruply lensed quasars.

Quasar-host galaxy decomposition

• The mass relations between supermassive black holes and their host galaxies at 1<z<2 with HST-WFC3; Ding et al. 2019

  Quasar host galaxy decomposition at high redshift on HST imaging and marginalization over PSF uncertainties.

• Testing the Evolution of the Correlations between Supermassive Black Holes and their Host Galaxies using Eight Strongly Lensed Quasars; Ding et al. 2020

  Quasar host galaxy decomposition with lensed quasars.

• A local baseline of the black hole mass scaling relations for active galaxies. IV. Correlations between MBH and host galaxy σ, stellar mass, and luminosity; Bennert et al. 2021

  Detailed measurement of galaxy morphology, decomposing in spheroid, disk and bar, and central AGN

• The Sizes of Quasar Host Galaxies with the Hyper Suprime-Cam Subaru Strategic Program; Li et al. 2021a

  Quasar-host decomposition of 5000 SDSS quasars

• The eROSITA Final Equatorial-Depth Survey (eFEDS): A multiwavelength view of WISE mid-infrared galaxies/active galactic nuclei; Toba et al. 2021

  Quasar-host decomposition of HSC imaging

• Synchronized Co-evolution between Supermassive Black Holes and Galaxies Over the Last Seven Billion Years as Revealed by the Hyper Suprime-Cam; Li et al. 2021b

  Quasar-host decomposition of SDSS quasars with HSC data

• Evidence for a milli-parsec separation Supermassive Black Hole Binary with quasar microlensing; Millon et al. 2022

  Using lenstronomy to generate the microlensed images of the accretion disk

Lensing of Gravitational Waves

• lensingGW: a Python package for lensing of gravitational waves; Pagano et al. 2020

  A Python package designed to handle both strong and microlensing of compact binaries and the related gravitational-wave signals.

• Localizing merging black holes with sub-arcsecond precision using gravitational-wave lensing; Hannuksela et al. 2020

  solving the lens equation with lenstronomy using lensingGW

• Lensing magnification: gravitational wave from coalescing stellar-mass binary black holes; Shan & Hu 2020

  lensing magnification calculations

• Identifying Type-II Strongly-Lensed Gravitational-Wave Images in Third-Generation Gravitational-Wave Detectors; Y. Wang et al. 2021

  solving the lens equation

• Beyond the detector horizon: Forecasting gravitational-wave strong lensing; Renske et al. 2021

  computing image positions, time delays and magnifications for gravitational wave forecasting

• A lensing multi-messenger channel: Combining LIGO-Virgo-Kagra lensed gravitational-wave measurements with Euclid observations; Wempe et al. 2022

  simulating Euclid-like simulations using lenstronomy and presenting a fast method to cacluate caustics for a PEMD+Shear model

Theory papers

• Line-of-sight effects in strong lensing: putting theory into practice; Birrer et al. 2017a

  This paper formulates an effective parameterization of line-of-sight structure for strong gravitational lens modelling and applies this technique to an Einstein ring in the COSMOS field

• Cosmic Shear with Einstein Rings; Birrer et al. 2018a

  Forecast paper to measure cosmic shear with Einstein ring lenses. The forecast is made based on lenstronomy simulations.

• Unified lensing and kinematic analysis for any elliptical mass profile; Shajib 2019

  Provides a methodology to generalize the multi-Gaussian expansion to general elliptical mass and light profiles

• Gravitational lensing formalism in a curved arc basis: A continuous description of observables and degeneracies from the weak to the strong lensing regime; Birrer 2021

  Lensing formalism with curved arc distortion formalism. Link to code repository `here <https://github.com/sibirrer/curved_arcs>`_.

Simulation products

• The LSST DESC DC2 Simulated Sky Survey; LSST Dark Energy Science Collaboration et al. 2020

  Strong lensing simulations produced by SLSprinkler utilizing lenstronomy functionalities

• The impact of mass map truncation on strong lensing simulations; Van de Vyvere et al. 2020

  Uses numerical integration to compute lensing quantities from projected mass maps from simulations.

Large scale structure

• Combining strong and weak lensingestimates in the Cosmos field; Kuhn et al. 2020

  inferring cosmic shear with three strong lenses in the COSMOS field

Others

• Predicting future astronomical events using deep learning; Singh et al.

  simulating strongly lensed galaxy merger pairs in time sequence

• Role of the companion lensing galaxy in the CLASS gravitational lens B1152+199; Zhang et al. 2022

  modeling of a double lensed quasar with HST and VLBI data