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Einstein ring

An Einstein ring is the simplest and most symmetrical manifestation of gravitational lensing, occurring when light from a distant astronomical source is bent by the immense gravitational field of a foreground massive object—such as a galaxy, galaxy cluster, or even a star—resulting in a circular ring of light encircling the lens when the source, lens, and observer are precisely aligned.^[1] This effect, first theoretically predicted by Albert Einstein in 1936 as a consequence of general relativity, arises because massive bodies curve spacetime, deflecting light rays by an angle given by α = 4GM/(c²b), where G is the gravitational constant, M is the mass of the lens, c is the speed of light, and b is the impact parameter.^[1]^[2] The phenomenon serves as a powerful tool in astrophysics for probing the universe's invisible structures, enabling precise measurements of the masses of lensing objects, including those dominated by dark matter, and providing insights into cosmic expansion and the distribution of matter on large scales.^[1]^[3] For instance, Einstein rings have been used to weigh isolated stellar remnants like the white dwarf Stein 2051 B, yielding a mass of 0.675 ± 0.051 solar masses through analysis of the ring's angular radius θ_E = √(4GM d_LS / (c² d_L d_S)), where d_L, d_S, and d_LS are the angular diameter distances to the lens, source, and between them, respectively.^[1] Notable observations include the Hubble Space Telescope's imaging of the Einstein ring around the galaxy ESO 325-G004, which distorts light from a background galaxy to confirm general relativity on galactic scales,^[4] and the Atacama Large Millimeter/submillimeter Array (ALMA)'s detailed view of a lensed galaxy forming a near-perfect ring, revealing internal structures otherwise obscured by distance.^[5] More recently, the Euclid space telescope identified a striking Einstein ring around the foreground galaxy NGC 6505, with the background source at approximately 4.42 billion light-years, highlighting the role of such lenses in mapping dark matter and studying galaxy evolution.^[3] These rare alignments, occurring due to the vast scales of the universe, not only validate Einstein's predictions but also amplify faint distant objects, allowing astronomers to observe phenomena billions of light-years away with unprecedented clarity.^[6]^[7]

Overview

Definition and Phenomenon

An Einstein ring is a nearly circular image formed by the gravitational lensing of light from a distant background source that is precisely aligned with a massive foreground lens and the observer, resulting in symmetric deflection of light rays around the lens.^[2] This phenomenon occurs as a special case of strong gravitational lensing, where the alignment creates a complete or partial ring of light encircling the lens position.^[3] The effect is named after Albert Einstein, who predicted it in a 1936 paper based on general relativity.^[6] The ring appears as a bright, arc-like or fully closed structure in astronomical images, with uniform brightness for a point-like source due to the symmetric bending of all light paths, though real observations often show slight asymmetries or distortions if the source is extended, such as a galaxy.^[8] Typical angular diameters range from fractions of an arcsecond to a few arcseconds, depending on the lens mass and distances involved.^[8] Physically, the process involves light from the background source traveling along curved paths in spacetime warped by the foreground lens's gravity, as described by general relativity, where massive objects curve spacetime and deflect photon trajectories symmetrically when alignment is perfect.^[2] Background sources can include quasars, galaxies, or even supernovae, while foreground lenses are typically galaxies, galaxy clusters, or theoretically black holes, all of which possess sufficient mass to produce the required deflection.^[9] For instance, the quasar MG1131+0456 forms a ring lensed by an intervening galaxy, observed as an oval with bright spots.^[9] In a more recent example, light from a galaxy 4.42 billion light-years away is lensed by the nearer galaxy NGC 6505 into a bright ring visible in Euclid telescope images.^[3]

Significance in Astrophysics

Einstein rings serve as powerful tools for measuring the total mass of foreground lensing objects, including the contributions from dark matter, by leveraging the symmetry of the ring structure to map the gravitational potential. The radius of the ring directly encodes the enclosed mass within the Einstein radius, allowing astronomers to determine the mass distribution with high precision, often revealing the dark matter fraction in the lens galaxy's core. For instance, in the case of the low-redshift lens NGC 6505, the Einstein ring enables estimation of the stellar mass as (1.06 ± 0.02) × 10¹¹ M_⊙ and a dark matter fraction of 0.12 ± 0.05 within the ring, highlighting the dominance of baryonic matter in such central regions while probing the initial mass function of stars.^[10] This approach is particularly effective for symmetric lenses, where deviations from perfect circularity can indicate substructure or asymmetries in the dark matter halo.^[11] In cosmology, Einstein rings facilitate estimates of angular diameter distances to both the lens and source galaxies, derived from the ring's geometry, which in turn supports measurements of the Hubble constant and the universe's expansion rate. By breaking degeneracies between lens mass models and cosmological parameters, these observations provide independent constraints on H₀, with values such as 82.4 ± 8.4 km/s/Mpc obtained from lensed systems like B1608+656 and RXJ1131–1231.^[12] Such distance ladders help calibrate supernova observations and refine models of cosmic acceleration driven by dark energy.^[11] The magnifying effect of Einstein rings amplifies the flux of faint background sources by factors up to 100 near caustics, enabling the detection and study of high-redshift galaxies and quasars that would otherwise be too dim for observation. This gravitational boost allows resolution of small-scale structures in these distant objects, such as the formation of early quasars or the internal dynamics of star-forming galaxies at z > 7, with magnification biases increasing the likelihood of detecting rare, compact sources.^[13] Einstein rings provide stringent tests of general relativity in strong gravitational fields by verifying the predicted deflection angles of light, where the parameter γ (spatial curvature per unit mass) is measured to be consistent with GR's value of 1. In the lens ESO 325-G004, analysis of the 2.95-arcsecond Einstein ring yields γ = 0.97 ± 0.09, confirming the theory's predictions extragalactically through combined imaging and kinematic data.^[14] For galaxy evolution, Einstein rings offer insights into the morphology and mass profiles of lensing galaxies, particularly massive ellipticals that dominate strong lensing events at z ≈ 0.5–1.0 due to their symmetric potentials and high central densities, allowing reconstruction of their structural evolution from z ~ 1–2 via mass-to-light ratio measurements within the Einstein radius.^[15] These observations trace how elliptical galaxies assemble their dark matter halos and stellar components over cosmic time. In large-scale surveys, Einstein rings are key targets for missions like the Euclid space telescope, which maps gravitational lensing to probe dark matter and energy, having already discovered complete rings such as that in NGC 6505 to weigh galactic cores.^[10]^[16] Similarly, the James Webb Space Telescope identifies rings in deep fields, enhancing hunts for high-redshift lenses and sources through its infrared sensitivity.^[17] More recent observations, as of August 2025, have used the Cosmic Horseshoe Einstein ring to detect an ultramassive black hole of approximately 36 billion solar masses, one of the largest known, demonstrating the potential for revealing extreme central engines in lensing galaxies.^[18] In October 2025, analysis of the Einstein ring around galaxy B1938+666 uncovered the smallest dark matter clump yet detected, with a mass of about 1 million solar masses, providing new constraints on dark matter substructure models.^[19]

Theoretical Foundations

Gravitational Lensing Principles

Gravitational lensing arises from the principles of general relativity, where massive objects curve spacetime, causing the paths of light rays from distant sources to deflect as they pass nearby, analogous to the focusing effect of an optical lens.^[20] This deflection occurs because light follows the shortest path in curved spacetime, with the angle of deflection being proportional to the mass of the lensing object and inversely proportional to the impact parameter of the light ray relative to the center of mass.^[21] Unlike traditional gravitational effects on massive particles, this phenomenon applies to massless photons, confirming Einstein's prediction that gravity influences all forms of energy propagation.^[22] Gravitational lensing manifests in several regimes depending on the lens mass, source-lens alignment, and distances involved. Strong lensing produces dramatic effects such as multiple images, extended arcs, or complete rings when the source is sufficiently aligned behind a massive foreground object like a galaxy or cluster.^[23] In contrast, weak lensing causes subtle distortions in the shapes of background galaxies, often used to map large-scale mass distributions, while microlensing involves transient brightenings from stellar-mass lenses, typically unresolved as multiple images.^[24] Einstein rings specifically emerge in the strong lensing regime under near-perfect alignment.^[25] The basic geometry of gravitational lensing involves an observer, a foreground lens (such as a galaxy), and a background source (like a quasar or distant galaxy) aligned nearly along the same line of sight. Without lensing, the source appears at its intrinsic angular position relative to the observer; with lensing, light rays from the source are bent by the lens's gravity, resulting in observed images at displaced angular positions that can be magnified or distorted.^[26] This setup requires the source to lie behind the lens from the observer's perspective, with the deflection mapping the unlensed source position to multiple lensed image positions.^[27] One key consequence of lensing is the magnification and distortion of the source's appearance, as multiple light paths from the source to the observer converge, increasing the apparent brightness without altering the surface brightness due to the conservation of photon flux in general relativity.^[21] Distortions manifest as shearing or stretching of the image, transforming point-like sources into arcs or rings in symmetric cases, which provides insights into the lens's mass profile.^[23] A common model for lensing galaxies assumes an isothermal sphere density profile, where the mass distribution follows \rho(r) \propto 1/r^2 for large radii, mimicking the velocity dispersion in galactic halos and yielding a deflection field that is symmetric and proportional to the angular distance from the lens center.^[21] This model simplifies calculations for strong lensing events, as it produces circularly symmetric effects ideal for interpreting observed arcs and rings.^[27] Unlike optical lensing, which relies on refraction through a medium with a wavelength-dependent refractive index, gravitational lensing involves pure geometric deflection of light paths in curved spacetime, making it achromatic—unaffected by the light's wavelength across the electromagnetic spectrum.^[28] This property allows lensing to amplify signals uniformly from radio to X-ray wavelengths, distinguishing it from dispersive optical effects.^[21]

Conditions for Einstein Ring Formation

For an Einstein ring to form, the background light source, the foreground gravitational lens, and the observer must exhibit near-perfect alignment along the line of sight, with the angular separation between the unlensed position of the source and the lens center being smaller than the characteristic Einstein radius. This precise geometric configuration ensures that light rays from all directions around the source are deflected symmetrically by the lens, producing a closed annular image. Deviations from this alignment result in partial arcs or multiple discrete images rather than a complete ring. The phenomenon arises from the deflection of light paths by the curvature of spacetime, as described in general relativity. The background source must be compact and ideally point-like or symmetrically extended to yield a sharp, uniform ring; extended sources, such as large galaxies, typically produce incomplete or distorted rings due to differential magnification across their structure. In practice, quasars or compact galaxies serve as suitable sources because their small angular size minimizes smearing effects. Conversely, the lens requires a massive, spherically symmetric mass distribution to maintain the circular symmetry of the ring; models like the singular isothermal sphere (SIS), which approximate the density profiles of elliptical galaxies or galaxy clusters, are commonly used to describe such lenses. Asymmetries in the lens mass, such as from mergers or substructure, disrupt the symmetry and lead to arc-like features instead of full rings. Redshift plays a crucial role in facilitating ring formation, with lenses typically residing at intermediate redshifts (z ≈ 0.1–1) where sufficient mass concentrations are available, while sources are at higher redshifts (z > 1) to maximize the lensing efficiency through increased angular diameter distances. Lenses at lower redshifts are rarer for rings because they generally possess insufficient mass to produce the necessary deflection angles. The overall probability of observing an Einstein ring remains low, with the optical depth for strong lensing events around 10^{-3} per potential lens system, reflecting the stringent alignment demands in a random universe. By 2025, systematic surveys such as those from the Hubble Space Telescope and the Euclid mission have identified approximately 100 confirmed Einstein rings, underscoring their scarcity despite advances in wide-field imaging. Environmental conditions further constrain ring visibility, requiring a relatively clear line of sight with minimal intervening interstellar or intergalactic matter to avoid dust absorption, scattering, or additional weak lensing that could obscure or distort the ring. Such pristine paths are more common in directions toward high-latitude fields but can be disrupted by galactic dust lanes or clustered environments around the lens.

Mathematical Description

Lens Equation

The lens equation in gravitational lensing relates the angular position \vec{\beta} of an unlensed source to the observed angular position \vec{\theta} of its image through the reduced deflection angle \vec{\alpha}(\vec{\theta}), expressed as \vec{\beta} = \vec{\theta} - \vec{\alpha}(\vec{\theta}).^[21] This vector equation, applicable in the small-angle approximation, maps the source plane to the image plane and determines the positions of multiple images or extended structures like Einstein rings.^[21] The equation relies on the thin lens approximation, which models the lensing mass distribution as a two-dimensional surface mass density \Sigma(\vec{\xi}) projected onto a single plane perpendicular to the line of sight, valid for most extragalactic lenses where the lens thickness is negligible compared to the source and lens distances.^[21] Under this approximation, the deflection angle \vec{\alpha} is computed by integrating the gravitational potential along the line of sight, simplifying calculations for distant observers.^[21] For a point-mass lens of mass M, the deflection angle is \hat{\alpha}(\hat{b}) = \frac{4GM}{c^2 \hat{b}}, where \hat{b} is the physical impact parameter and c is the speed of light; in angular coordinates, the reduced deflection becomes \vec{\alpha}(\vec{\theta}) = \frac{4GM}{c^2} \frac{D_{ds}}{D_d D_s} \frac{\vec{\theta}}{|\vec{\theta}|^2}, with D_d, D_{ds}, and D_s denoting the angular diameter distances to the lens, between lens and source, and to the source, respectively.^[21] This form generalizes to extended mass distributions via \vec{\alpha}(\vec{\theta}) = \frac{1}{\pi} \int \kappa(\vec{\theta}') \frac{\vec{\theta} - \vec{\theta}'}{|\vec{\theta} - \vec{\theta}'|^2} d^2\theta', where \kappa(\vec{\theta}) = \Sigma(\vec{\theta}) / \Sigma_{\rm cr} is the dimensionless convergence and \Sigma_{\rm cr} is the critical surface density.^[21] In cases of perfect alignment where \vec{\beta} = 0, circular symmetry in the lens potential yields a closed ring image at angular radius \theta = \theta_E, the Einstein radius, satisfying \theta_E = |\vec{\alpha}(\theta_E)|.^[21] This configuration produces the characteristic Einstein ring, with the equation's solutions degenerating into a continuum of points on the ring due to azimuthal symmetry.^[21] A common model for galaxy-scale lenses is the singular isothermal sphere (SIS), with three-dimensional density \rho(r) = \sigma_v^2 / (2\pi G r^2) where \sigma_v is the velocity dispersion, leading to a deflection angle of constant magnitude \alpha(\theta) = \theta_E for \theta > 0, with \theta_E = 4\pi (\sigma_v^2 / c^2) (D_{ds} / D_s).^[21] This model, which reproduces observed flat rotation curves, often produces near-perfect Einstein rings under alignment, as the constant deflection simplifies the lens equation to \beta = \theta - \theta_E \operatorname{sign}(\theta).^[21] For asymmetric mass distributions or misaligned sources (\beta \neq 0), the lens equation generally requires numerical methods such as iterative solvers or ray-tracing algorithms to find image positions, though exact rings occur only in the symmetric \beta = 0 case.^[29]

Derivation of Ring Radius

The Einstein radius, denoted \theta_E, represents the angular radius of the ring image formed when a distant point source is perfectly aligned with a foreground lens and the observer, under the assumption of circular symmetry in the lens mass distribution. This radius provides a characteristic scale for the strength of gravitational lensing, directly tying the observed ring size to the lens mass and the geometry of the system.^[30] For a point-mass lens of mass M, the derivation begins with the deflection angle experienced by a light ray passing at a physical impact parameter b from the lens: \hat{\alpha}(b) = \frac{4GM}{c^2 b}, where G is the gravitational constant and c is the speed of light. In angular coordinates, the impact parameter is b = D_l \theta, with D_l the angular diameter distance from the observer to the lens and \theta the angular position of the image. The reduced deflection angle in the lens equation is then \alpha(\theta) = \frac{D_{ls}}{D_s} \cdot \frac{4GM}{c^2 D_l \theta}, where D_s is the angular diameter distance to the source and D_{ls} is the distance from lens to source. For perfect alignment, the unlensed source position \beta = 0, so the lens equation \beta = \theta - \alpha(\theta) simplifies to \theta = \alpha(\theta). Substituting yields \theta^2 = \frac{4GM}{c^2} \frac{D_{ls}}{D_l D_s}, hence the Einstein radius is \theta_E = \sqrt{\frac{4GM}{c^2} \frac{D_{ls}}{D_l D_s}}.^[30]^[31] This derivation extends to more realistic extended mass distributions, such as the singular isothermal sphere (SIS) model, which approximates galaxies with a density profile \rho(r) = \frac{\sigma_v^2}{2\pi G r^2}, where \sigma_v is the one-dimensional velocity dispersion. For an SIS lens, the deflection angle is constant with impact parameter, \alpha(\theta) = \frac{4\pi \sigma_v^2}{c^2} \frac{D_{ls}}{D_s}, independent of \theta. In the aligned case (\beta = 0), the lens equation again gives \theta_E = \alpha(\theta_E), yielding \theta_E = 4\pi \frac{\sigma_v^2}{c^2} \frac{D_{ls}}{D_s}. This formula relates the ring size directly to the lens's kinematic properties rather than total mass.^[30]^[31] In typical astronomical scenarios, \theta_E for galaxy-scale lenses (masses around $10^{11}-10^{12} M_\odot) ranges from a fraction of an arcsecond to several arcseconds, while for massive galaxy clusters ($10^{14} M_\odot or more), it can reach tens of arcseconds, reflecting the increased lensing efficiency with mass and favorable source-lens distances. These derivations assume perfect circular symmetry in the lens potential, which real systems rarely achieve; asymmetries from substructure or external shear perturb the ring into arcs or incomplete images, reducing its perfection.^[32]^[30]

Historical Development

Prediction by Einstein

In 1912, while developing the foundations of general relativity, Albert Einstein explored the idea of gravitational lensing in his private research notes, deriving the basic equations for light deflection by a point mass and considering the formation of multiple images from a background source. These calculations, recorded in his Prague notebook, anticipated the ring-like configuration but were not published at the time.^[33] The concept of an Einstein ring was first proposed in published literature by Russian physicist Orest Chwolson in 1924, who described the possibility of ring-like images formed by gravitational lensing of stars. Nearly a quarter-century later, in 1936, Einstein published his theoretical prediction of the Einstein ring effect, prompted by a letter from Czech electrical engineer Rudi W. Mandl, who inquired about stars acting as gravitational lenses.^[20] In the short article "Lens-Like Action of a Star by the Deviation of Light in the Gravitational Field," appearing in Science volume 84, pages 506–507, Einstein calculated that for a point-mass lens like a star of the Sun's mass, perfect alignment of source, lens, and observer would produce a symmetric ring image with an angular radius on the order of $10^{-6} arcseconds.^[20] He emphasized the extreme rarity of such precise alignments and the minuscule size of the effect, concluding that it would be "devoid of any practical interest" with contemporary observational technology.^[20] Einstein initially resisted publishing the work, expressing reluctance in correspondence with Mandl due to its perceived triviality and fear of ridicule from astronomers, whom he believed would dismiss the unobservable phenomenon.^[33] Despite this hesitation, the publication highlighted the theoretical possibility within general relativity, where light bending by gravity could create closed ring images under ideal symmetric conditions, building on Chwolson's earlier idea with explicit calculations. Einstein's 1936 paper directly inspired subsequent theoretical extensions, notably Fritz Zwicky's 1937 proposal that extended-mass systems like galaxies or clusters could produce larger, more detectable lensing rings due to their greater gravitational influence.^[34] Zwicky, referencing Einstein's calculations, argued in "Nebulae as Gravitational Lenses" (Physical Review 51, 290) that such configurations offered better prospects for observation.^[34]

First Observations

The search for Einstein rings gained momentum in the late 1970s following theoretical work by Bohdan Paczyński, who emphasized the potential for detecting gravitational lensing effects in quasar observations, prompting systematic surveys for lensed systems. Although no confirmed rings were identified immediately, this theoretical foundation facilitated the identification of the first gravitational lens candidate in 1979 (Q0957+561), which highlighted the feasibility of lensing phenomena and spurred radio telescope campaigns. The first confirmed Einstein ring, designated MG 1131+0456, was detected in 1987 using the National Radio Astronomy Observatory's Very Large Array (VLA) during a survey for compact radio sources.^[9] This radio observation revealed an oval structure consisting of four bright images of a distant quasar lensed by a foreground galaxy at redshift z ≈ 0.84, forming a near-complete ring with an angular diameter of about 2 arcseconds. Initial confirmation relied on high-resolution radio mapping, as optical counterparts were faint and required subsequent multi-wavelength follow-up to rule out alternative explanations like intrinsic source structure.^[35] In the early 1990s, radio surveys expanded the catalog of Einstein rings. The Jodrell Bank-VLA Astrometric Survey (JVAS) identified B1938+666 in 1992 as a quadruply imaged quasar system with prominent radio arcs suggestive of ring formation, lensed by an elliptical galaxy at redshift z = 0.881. Radio observations showed a thin arc from merged images of the quasar's radio lobe, confirming the ring geometry, while optical and infrared imaging in 1998 using the Hubble Space Telescope's Near Infrared Camera and Multi-Object Spectrometer (NICMOS) revealed a complete infrared Einstein ring approximately 1 arcsecond in diameter.^[36] This multi-wavelength approach was essential, as early radio detections often mimicked arcs from other phenomena, such as supernova remnants or scattering, necessitating optical confirmation to verify the lensing nature.^[37] Advancements in optical astronomy led to clearer examples in the late 1990s. The Cosmic Lens All-Sky Survey (CLASS) discovered B1608+656 in 1999 as a quadruple lens with radio components, but Hubble Space Telescope (HST) imaging in 1998-2000 captured a prominent optical and infrared Einstein ring encircling two interacting lens galaxies at z ≈ 0.63, demonstrating extended source emission distorted into a near-perfect circle. This system exemplified the challenges of early observations, where partial arcs were frequently confused with tidal tails or other gravitational interactions until HST's high resolution provided unambiguous ring morphology.^[38] By the early 2000s, dedicated lens surveys accelerated discoveries. The Sloan Lens ACS Survey (SLACS), initiated around 2004 using Sloan Digital Sky Survey data and HST Advanced Camera for Surveys follow-up, identified approximately 100 strong lens systems by 2008, including several Einstein rings such as the double-ring system SDSS J0946+1006 (z_lens = 0.222), where concentric rings from sources at z = 0.609 and z = 1.289 highlighted complex multi-plane lensing.^[39] These findings underscored the rarity of perfect alignments, with only about 10 confirmed Einstein rings (primarily radio and a few optical) known by 2000, emphasizing the need for deep, multi-wavelength imaging to distinguish true rings from incomplete arcs.^[6]

Observational Examples

Early Discoveries

The period from 2005 to 2010 marked significant progress in identifying Einstein rings through large-scale surveys combining ground-based and space-based observations. The COSMOS survey, utilizing the Hubble Space Telescope (HST), contributed to the discovery of multiple gravitational lens systems exhibiting ring-like structures in deep fields, enhancing the catalog of known examples by leveraging high-resolution imaging to resolve faint arcs.^[40] In 2007, the Sloan Digital Sky Survey (SDSS) identified the Cosmic Horseshoe (SDSS J1004+4112), a nearly complete Einstein ring formed by the alignment of a luminous red galaxy at redshift z ≈ 0.44 lensing a background galaxy at z ≈ 2.38, representing one of the most symmetric partial rings observed at the time.^[41] This era also saw the first confirmed galaxy-galaxy Einstein ring, LRG 3-757, discovered in SDSS Data Release 5, where a massive foreground elliptical galaxy at z ≈ 0.48 creates a ~300° arc around a background source, providing insights into early galaxy assembly.^[42] Confirmation of such systems increasingly relied on advanced techniques like adaptive optics to sharpen ground-based images and integral field spectroscopy to map velocity fields and redshifts, distinguishing true rings from chance alignments.^[43] Entering the 2010s, surveys such as the Canada-France-Hawaii Telescope Lensing Survey (CFHTLenS), part of the broader CFHT Legacy Survey, systematically hunted for strong lenses and identified approximately 20 additional Einstein ring candidates through shear analysis and follow-up imaging, focusing on massive early-type galaxies as lenses.^[44] Similarly, the Dark Energy Survey (DES), beginning in 2013, contributed ring discoveries using the Dark Energy Camera, including a notable example in 2016 that highlighted the survey's role in expanding the sample. A representative case from this period is the system around SDSS J1206+4332, where high-resolution spectroscopy in 2012 revealed lensing features consistent with quasar alignment at source redshift z ≈ 1.79, aiding in ring-like arc characterization.^[45] Most early Einstein rings from this timeframe involved quasar or galaxy sources lensed by foreground galaxies at redshifts z ≈ 0.5–2, often detected in hybrid radio-optical observations that combined SDSS photometry with radio interferometry for robust identification.^[46] By 2015, these efforts had confirmed around 50 Einstein rings, building comprehensive catalogs that underscored the rarity and scientific value of perfect alignments.

Recent Discoveries

In July 2022, the James Webb Space Telescope (JWST) released its first deep-field image of the galaxy cluster SMACS 0723, revealing numerous gravitational lensing arcs that form partial Einstein rings around distant background galaxies, showcasing the cluster's massive gravitational influence at a redshift of z ≈ 0.39.^[47] These observations, taken during JWST's early science phase, highlighted the telescope's ability to resolve intricate lensing structures in unprecedented detail, aiding in the study of early universe galaxy formation.^[48] In February 2025, the Euclid space telescope identified a complete Einstein ring surrounding the elliptical galaxy NGC 6505 at a redshift of z = 0.042, marking one of the nearest known examples at approximately 590 million light-years away and captured via its wide-field visible and near-infrared imaging.^[3] This discovery, the first strong gravitational lens found by Euclid during its early operations, allowed precise mapping of the lens's mass distribution, including its dark matter halo, through the symmetric ring's alignment.^[10] The ring's clarity enabled astronomers to weigh the galaxy's total mass, confirming general relativity's predictions in a nearby system.^[49] Later in 2025, JWST's COSMOS-Web survey in deep fields uncovered eight strong gravitational lenses, including several full Einstein rings at high redshifts (z > 1), providing robust tests of general relativity in extreme cosmic environments.^[50] These findings, released in September, demonstrated lensing efficiencies that align with Einstein's theory, with ring distortions revealing galaxy morphologies billions of light-years away.^[51] By 2025, catalogs of confirmed strong gravitational lenses, including Einstein rings, had grown to approximately 1000, driven by these advanced surveys.^[52] Advances in detection include AI-assisted algorithms tested on Legacy Survey of Space and Time (LSST) preview data, which identified over 1,200 gravitational lens candidates by 2021, accelerating the search for rare full rings amid vast datasets.^[53] Emerging multi-messenger connections link Einstein rings to gravitational wave events, as lensing models predict amplified signals from binary mergers, enabling joint analyses of waveform distortions and optical rings.^[54] These recent rings have refined dark matter distribution maps in galaxy halos, with symmetric examples like NGC 6505 constraining halo profiles to within 10% accuracy.^[10] They also support efforts to resolve the Hubble constant (H0) tension through time-delay cosmography, where ring light paths yield expansion rate measurements consistent with local values around 73 km/s/Mpc.^[55]

Advanced Phenomena

Multiple and Partial Rings

In gravitational lensing, perfect alignment of the source, lens, and observer is exceedingly rare, leading to deviations from ideal Einstein rings that manifest as partial rings or arcs when the source is slightly misaligned with the lens center.^[56] These arcs form as segments of what would otherwise be a complete ring, with the extent of completeness depending on the angular offset; for instance, offsets on the order of arcseconds produce prominent but incomplete loops visible in optical and infrared observations.^[57] In the case of point-like sources such as quasars, slight misalignment can result in the four-image configuration known as an Einstein cross, where the lens—often a foreground galaxy—splits the light into a cross-shaped pattern, representing the limit of multiple arc formation without ring closure.^[58] Multiple Einstein rings, appearing as nested or concentric structures, arise in rare scenarios involving multi-plane lensing, where light passes through multiple deflecting masses along the line of sight, or due to substructure within galaxy clusters that creates distinct lensing planes.^[59] These configurations produce inner and outer rings from the same background source, with the outer ring typically formed by the primary lens and the inner by secondary deflectors; a notable example is the double ring system SDSS J0946+1006, observed by the Hubble Space Telescope, where two galaxies at different redshifts amplify the effect.^[60] Such nested rings require precise multi-alignments that are statistically improbable in standard single-plane scenarios.^[61] Faint secondary or "extra" rings can emerge from perturbations caused by lens subhalos—small dark matter concentrations—or multiplicity in the background source, distorting the primary ring into additional faint loops or image pairs.^[62] In the lens system JVAS B1938+666, high-resolution observations have revealed such subhalo-induced distortions, manifesting as subtle secondary features within the main Einstein ring, which highlight the presence of low-mass dark matter clumps otherwise invisible to direct detection.^[63] Compound lenses, such as those involving binary black holes or merging galaxies, generate asymmetric rings due to the non-spherical mass distribution, resulting in elongated, warped, or fragmented arcs rather than symmetric circles. These irregularities arise from the combined deflection fields of the binary components, producing caustics that map the source into uneven multiple images or partial rings with varying brightness.^[64] Recent observations by the James Webb Space Telescope (JWST) in 2025 have captured several partial Einstein rings, including arcs around elliptical galaxies that reveal intricate source structures through gravitational magnification.^[17] For example, JWST imaging of systems like the spiral-elliptical alignment in the SLICE survey showcases incomplete rings with arc lengths spanning tens of arcseconds, demonstrating the prevalence of these misaligned configurations over full rings.^[65] These non-ideal ring forms break the radial symmetry of perfect lensing, providing critical insights into lens complexity, such as the distribution of dark matter substructure, by analyzing distortions that trace mass concentrations down to scales of 10^8 solar masses.^[62]

Simulations and Modeling

Simulations of Einstein rings primarily rely on ray-tracing techniques, which involve backward integration of light paths from the observer plane through the gravitational potential of the lens to the source plane, enabling the prediction of lensed image configurations such as ring morphologies.^[66] This method approximates the deflection of light rays using the weak-field limit of general relativity, where the lens potential is derived from the projected surface mass density, and is particularly effective for modeling axisymmetric or nearly symmetric systems that produce complete rings.^[67] Key software tools for these simulations include Lenstool, a Bayesian modeling package that employs parametric profiles to reconstruct lens mass distributions and generate simulated images; GravLens, which supports the creation of extended images like Einstein rings by specifying lens and source parameters; and PyAutoLens, an open-source Python library that automates strong lensing modeling with GPU acceleration via JAX, facilitating rapid iteration over parameter spaces.^[68]^[69]^[70] For more complex scenarios involving evolving lenses, N-body simulations from cosmological datasets, such as those combining dark matter halos with baryonic components, are integrated to trace the formation and lensing efficiency of galaxy-scale structures over cosmic time.^[71] The modeling process typically begins with specifying the lens mass profile, such as the singular isothermal ellipsoid (SIE) model, which assumes an elliptical distribution of mass with a core velocity dispersion, alongside the source position and redshift; rays are then traced through the resulting deflection field to produce output images, magnification maps, and flux ratios based on the lens equation. These simulations allow for iterative fitting to refine parameters like the lens ellipticity and source orientation, yielding predictions of ring diameter and brightness distributions that align with the thin-lens approximation. Applications of these simulations extend to forecasting Einstein ring detections in large-scale surveys, where they predict the expected morphology and frequency of rings to optimize search algorithms, and to analyzing observed systems by inferring lens properties such as the stellar velocity dispersion σ_v from ring geometry.^[72] For instance, simulated rings help calibrate the sensitivity of surveys to alignment conditions required for complete rings, typically occurring when the source lies near the lens optical axis. Simulations incorporating substructure, such as dark matter clumps or line-of-sight halos, reveal perturbations in ring structure, including faint companion images or asymmetries, which reproduce observed deviations from perfect symmetry and enable constraints on the subhalo mass function.^[71]^[73] Looking ahead, GPU-accelerated frameworks like JAXtronomy and GIGA-Lens are poised to handle the volume of data from upcoming surveys such as the Legacy Survey of Space and Time (LSST), enabling real-time modeling of thousands of potential rings.^[74]^[75] Advanced simulations are beginning to incorporate general relativistic effects beyond the weak-field approximation for precise time-delay measurements in ring systems.

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Apr 7, 2015 · Gravitational lensing occurs when a massive galaxy or cluster of galaxies bends the light emitted from a more distant galaxy, forming a highly ...
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Einstein's Rings in Space | Center for Astrophysics
Nov 17, 2005 · When both galaxies are exactly lined up, the light forms a bull's-eye pattern, called an Einstein ring, around the foreground galaxy.
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Put a Ring On It: How Gravity Gives Astronomers a Powerful Lens ...
Sep 14, 2022 · Gravity can change the path of light, and sometimes focuses the light of distant galaxies to create a gravitational lens or Einstein Ring.
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Einstein Rings - an overview | ScienceDirect Topics
An Einstein ring is defined as the circular pattern of light created when light from a distant source star is deflected by a massive body, resulting in a ...
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Discovery of the First "Einstein Ring" Gravitational Lens
In 1936, Einstein himself showed that, if a brightly-emitting object were exactly behind a massive body capable of making a gravitational lens, the result ...
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Euclid: A complete Einstein ring in NGC 6505
Both Einstein rings and lensed point sources have tremendous scientific value and have been used in a wide variety of applications. When the source is time- ...Missing: appearance | Show results with:appearance
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The Importance of Einstein Rings - NASA ADS
The Einstein rings break the degeneracies in the mass distributions or Hubble constants inferred from observations of gravitational lenses.Missing: estimates | Show results with:estimates
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A measurement of the Hubble constant from angular diameter ...
Sep 13, 2019 · The local expansion rate of the Universe is parametrized by the Hubble constant, H 0 , the ratio between recession velocity and distance.
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Galaxies as High-resolution Telescopes - IOP Science
Sep 13, 2017 · The magnification close to the caustic as high as ∼100 will allow us to detect and resolve the formation of the first quasars. 5. Astrometry.
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[PDF] A precise extragalactic test of General Relativity - ESO
Hubble Space Telescope (HST) imaging of E325 serendipitously revealed the presence of an Einstein ring with 2.95 arcsec- ond radius around the centre of the ...
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[PDF] 12 Strong Gravitational Lenses - The LSST Science Book
We expect the galaxy-scale lens population to be dominated by massive elliptical galaxies at red- shift 0.5–1.0, whose background light sources are the ...<|separator|>
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Euclid Consortium – A space mission to map the Dark Universe
### Summary of Euclid's Mission Goals on Gravitational Lensing Surveys and Einstein Rings
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Spying a spiral through a cosmic lens - ESA/Webb
Mar 27, 2025 · The lensing galaxy at the center of this Einstein ring is an elliptical galaxy, as can be seen from the galaxy's bright core and smooth, ...Missing: morphology | Show results with:morphology
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Lens-Like Action of a Star by the Deviation of Light in the ... - Science
Lens-Like Action of a Star by the Deviation of Light in the Gravitational Field. Albert EinsteinAuthors Info & Affiliations. Science. 4 Dec 1936.
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[PDF] Lectures on Gravitational Lensing - arXiv
Lensing therefore offers an ideal way to detect and study dark matter, and to explore the growth and structure of mass condensations in the universe.
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A brief history of gravitational lensing - Einstein-Online
Einstein himself mentions the phenomenon in a letter written on December 15, 1915 to his friend Heinrich Zangger (1874-1957), a professor of forensic medicine ...
[20]
Gravitational Lensing | Center for Astrophysics | Harvard ...
Even the gravity from planets affects light, allowing researchers to detect worlds in orbit around other stars. This effect is called “gravitational lensing”, ...
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Hubble Gravitational Lenses - NASA Science
such as a galaxy cluster — warps space and time causing light to bend, distort, and magnify ...
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Gravitational Lensing - ESA/Webb
such as a galaxy cluster — causes a sufficient curvature of spacetime for the path of light ...
[23]
basic concepts of gravitational lensing
The angular distances from observer to lens, from observer to source, and from lens to source are respectively Dd, Ds, and Dds. But natural gravitational lenses ...
[24]
[PDF] Introduction to Gravitational Lensing
2.4 Magnification and distortion. One of the main features of gravitational lensing is the distortion which it introduces into the shape of the sources. This ...<|separator|>
[25]
Modern Cosmological Observations and Problems - G. Bothun
Gravitational lensing is achromatic. There is no equivalent to the index of refraction for a normal lens as the behavior of light passing through curved ...
[26]
[PDF] NUMERICAL METHODS IN GRAVITATIONAL LENSING MPI F ¨UR ...
Points on the source plane next to the caustic curve are then easily found via the lens equation, ~yCij =~xCij −~α(~xCij), ... Deflection Angles of Asymmetric ...
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https://www.ita.uni-heidelberg.de/~jmerten/misc/meneghetti_lensing.pdf
[28]
[PDF] Week 7: Gravitational Lensing
... Einstein ring” at a radius θI that satisfies α(θI) = θI. For a point-mass lens, this “Einstein radius” is. θE = 4GM c2. DLS. DLDS. 1/2. = M. 1011.09 M⊙. 1/2.
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[PDF] Gravitational Lensing - Michigan State University
No complete Einstein ring has been found around clusters due to the facts that most clusters are not really spherical mass distributions and since the align-.
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[PDF] Mandl, Einstein, and the Early History of Gravitationa - MPIWG
The Origin of Gravitational Lensing: A Postscript to. Einstein's 1936 Science Paper. Science 275, 184-186. Russell, H. N. (1937). A Relativistic Eclipse ...
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https://kamion.pha.jhu.edu/Ay127/week7.pdf
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A Redshift for the First Einstein Ring, MG 1131+0456 - ADS
A Redshift for the First Einstein Ring, MG 1131+0456. Stern, Daniel; ;; Walton ... MG 1131+0456 is a radio-selected gravitational lens, and is the first known ...
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A complete infrared Einstein ring in the gravitational lens system ...
Oct 15, 1997 · We report the discovery, using NICMOS on the Hubble Space Telescope, of an arcsecond-diameter Einstein ring in the gravitational lens system B1938+666.
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A complete infrared Einstein ring in the gravitational lens system ...
We report the discovery, using NICMOS on the Hubble Space Telescope, of an arcsec-diameter Einstein ring in the gravitational lens system B1938 + 666.
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The Hubble Constant from the Gravitational Lens B1608+656 - arXiv
We present a refined gravitational lens model of the four-image lens system B1608+656 based on new and improved observational constraints.Missing: 1998 | Show results with:1998
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The Sloan Lens ACS Survey. VI. Discovery and Analysis of a Double ...
We report the discovery of two concentric Einstein rings around the gravitational lens SDSS J0946+1006. The main lens is at redshift zl = 0.222, while the inner ...
[37]
Hubble, Sloan Quadruple Number of Known Optical Einstein Rings
Nov 17, 2005 · Among these 19, they have found eight new so-called "Einstein rings," which are perhaps the most elegant manifestation of the lensing phenomenon ...<|separator|>
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Discovery of an Einstein Ring around a Giant Luminous Red Galaxy
We report the discovery of an almost complete (~300°) Einstein ring of diameter 10′′ in Sloan Digital Sky Survey (SDSS) Data Release 5 (DR5). Spectroscopic data ...
[39]
Discovery of an Einstein Ring around a Giant Luminous Red Galaxy
Jun 15, 2007 · We report the discovery of an almost complete Einstein ring of diameter 10" in Sloan Digital Sky Survey (SDSS) Data Release 5 (DR5).Missing: 2005-2010 | Show results with:2005-2010
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[PDF] Observing the Cosmic Horseshoe
Mar 25, 2015 · (2007) reported the discovery of an almost complete Einstein ring around a giant luminous red galaxy (figure 1) in Sloan Digital Sky Survey ...
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https://iopscience.iop.org/article/10.1086/524948
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Spectroscopy and high-resolution imaging of the gravitational lens ...
Mar 7, 2016 · In this paper, we focus on a quite unusual and remarkable system, the doubly lensed quasar SDSS J1206+4332. It was discovered by. Oguri et al. ( ...
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A Redshift for the First Einstein Ring, MG 1131+0456 - IOPscience
Jun 1, 2020 · Separating the lens from the source reveals the background Einstein ring to be extremely red, with R = 23.3 and K = 17.8 (Annis 1992).
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Einstein ring - Wikipedia
An Einstein Ring is a special case of gravitational lensing, caused by the exact alignment of the source, lens, and observer. This results in symmetry ...Introduction · History · Extra rings · Gallery
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NASA's Webb Delivers Deepest Infrared Image of Universe Yet
Jul 12, 2022 · Thousands of galaxies flood this near-infrared image of galaxy cluster SMACS 0723. High-resolution imaging from NASA's James Webb Space ...Missing: Einstein | Show results with:Einstein
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Unscrambling the Lensed Galaxies in JWST Images behind SMACS ...
Oct 13, 2022 · 5. Summary. We presented a new JWST parametric model for the massive cluster SMACS 0723, incorporating new multiple image family constraints ...
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Euclid Discovers Einstein Ring in Our Cosmic Backyard
Feb 10, 2025 · Euclid Archive Scientist Bruno Altieri noticed a hint of an Einstein ring among images from the spacecraft's early testing phase in September ...
[48]
The James Webb telescope proves Einstein right, 8 times over
Oct 5, 2025 · What it is: Eight "Einstein rings," officially known as gravitational lenses ; Where it is: The deep sky ; When it was shared: Sept. 30, 2025.
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COSMOS-Web unveils JWST's newest gravitational lenses - Medium
Oct 13, 2025 · By deeply imaging a large volume of space, COSMOS-Web provides JWST's widest cosmic views. Its gravitational lenses reveal a big surprise.
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Euclid finds complete Einstein Ring in NGC galaxy
Feb 10, 2025 · But only Albert Einstein was able to calculate the correct angle of light-bending, using his General Theory of Relativity in 1915.<|control11|><|separator|>
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Astronomers 'Unscramble' Einstein Ring to Reveal Star Formation in ...
Jun 8, 2015 · Astronomers 'Unscramble' Einstein Ring to Reveal Star Formation in the Distant Universe. Gravitationally lensed galaxy SDP.81. Credit: ALMA ( ...Missing: SPT- J2344- 4243 2023-2025
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https://www.euclid-ec.org/einstein-ring-in-ngc-6505/
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AI Finds More Than 1200 Gravitational Lensing Candidates
Feb 2, 2021 · A research team has found more than 1200 possible gravitational lenses – objects that can be markers for the distribution of dark matter.<|separator|>
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Multi-messenger Gravitational Lensing - arXiv
Mar 25, 2025 · We introduce the rapidly emerging field of multi-messenger gravitational lensing – the discovery and science of gravitationally lensed phenomena in the distant ...
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'Einstein rings' around distant galaxies inch us closer to solving dark ...
Apr 27, 2023 · This distortion of light is called “gravitational lensing,” and the circles it can create are called “Einstein rings.” By studying how the rings ...Missing: definition | Show results with:definition<|control11|><|separator|>
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Evolving Morphology of Resolved Stellar Einstein Rings - IOPscience
We study Einstein rings that may form around nearby stellar lenses. It is remarkable that these rings are bright and large enough to be detected and resolved ...Missing: CFHTLenS | Show results with:CFHTLenS
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The lens and source of the optical Einstein ring gravitational lens ER ...
... alignment between visible matter and total matter distributions in lens galaxies and found they have an RMS misalignment <10°. Our result adds weight to ...
[58]
The Gravitational Lens G2237 + 0305 - NASA Science
Mar 20, 2025 · The photograph shows four images of a very distant quasar which has been multiple-imaged by a relatively nearby galaxy acting as a gravitational lens.
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[0804.3744] On Multiple Einstein Rings - arXiv
Apr 23, 2008 · Abstract: A number of recent surveys for gravitational lenses have found examples of double Einstein rings.Missing: nested | Show results with:nested
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Hubble Finds Double Einstein Ring - NASA Science
Jan 10, 2008 · When both galaxies are exactly lined up, the light forms a circle, called an "Einstein ring," around the foreground galaxy. If another ...
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On multiple Einstein rings - Oxford Academic
Surprisingly, we show that it is possible for a single source to produce more than one Einstein ring. If two point masses, or two isothermal spheres, in ...
[62]
A Dense Dark Matter Core of the Subhalo in the Strong Lensing ...
Sep 19, 2025 · Given the Einstein ring radius of JVAS B1938+666 is r = 6.4 kpc, the ... subhalo to a simulated strong gravitational lens system similar to JVAS ...
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SHARP – I. A high-resolution multiband view of the infrared Einstein ...
At the same time, with so many constraints placed on the model, Einstein ring lenses are sensitive to perturbations from the smooth gravitational potential of ...Missing: environmental | Show results with:environmental
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Frequency shift in binary microlensing - Oxford Academic
Gravitational microlensing with binary lensing is one of the channels for detecting exoplanets. Due to the degeneracy of the lens parameters for the binary ...
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Webb spies a spiral through a cosmic lens - ESA
Mar 27, 2025 · Einstein rings occur when light from a very distant object is bent (or 'lensed') about a massive intermediate (or 'lensing') object. This is ...
[66]
Gravitational lensing: numerical simulations with a hierarchical tree ...
The general microlensing equation then is(7) y = 1−γ 0 0 1+γ x −σ c x − ∑ i=1 N ∗ m i ( x − x i ) ( x − x i ) 2 , where the macromodel of the gravitational lens ...
[67]
Gravitational lensing with three-dimensional ray tracing
Gravitational lensing causes magnification or demagnification of Type Ia supernovae (SNeIa), resulting in a scatter in the inferred distance–redshift ...Abstract · GRAVITATIONAL LENSING · RAY TRACING · COMPACT LENS MODELS
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LENSTOOL: A Gravitational Lensing Software for Modeling Mass ...
LENSTOOL: A Gravitational Lensing Software for Modeling Mass Distribution of ... We describe a procedure for modelling strong lensing galaxy clusters ...
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[PDF] gravlens 1.06 Software for Gravitational Lensing Chuck Keeton
A lens usually consists of some number of point-like images and/or extended images such as host galaxy arcs or an Einstein ring; the code allows you to use some ...
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[PDF] PyAutoLens: Open-Source Strong Gravitational Lensing
Feb 20, 2021 · PyAutoLens is an open-source Python 3.6+ package for strong gravitational lensing, with core features including fully automated strong lens ...
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Simulations of strong gravitational lensing with substructure
Galactic-sized gravitational lenses are simulated by combining a cosmological N-body simulation and models for the baryonic component of the galaxy.
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A Computer Vision Approach to Identify Einstein Rings and Arcs
Mar 31, 2017 · We present an Einstein ring recognition approach based on computer vision techniques. The workhorse is the circle Hough transform that recognise circular ...<|separator|>
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Modelling the line-of-sight contribution in substructure lensing - arXiv
Oct 13, 2017 · We investigate how Einstein rings and magnified arcs are affected by small-mass dark-matter haloes placed along the line-of-sight to gravitational lens systems.
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lenstronomy/JAXtronomy - GitHub
JAX port of lenstronomy, for parallelized, GPU accelerated, and differentiable gravitational lensing and image simulations.
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[2504.01302] GPU-Accelerated Gravitational Lensing & Dynamical ...
Apr 2, 2025 · We develop a methodology and software framework for joint modeling of stellar kinematics and lensing data.Missing: LSST | Show results with:LSST
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Lens Model Accuracy in the Expected LSST Lensed AGN Sample
Oct 23, 2025 · In the best-case scenario, GPU-accelerated models have reached modeling times down to 5 GPU hours per lens (e.g Huang et al., 2025; Galan et al.