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Virgo Supercluster

The Virgo Supercluster is a massive gravitational aggregation of approximately 100 galaxy groups and clusters, spanning a diameter of about 110 million light-years (33 megaparsecs), and serving as one of the largest known structures in the local universe.^[1] It encompasses an estimated 2,500 large galaxies and around 25,000 dwarf galaxies within a volume roughly 100 million light-years across, making it a key example of the filamentary large-scale structure observed in cosmic web surveys. The Virgo Supercluster is now understood to be part of the larger Laniakea Supercluster.^[2]^[3] At its core lies the Virgo Cluster, the nearest major cluster to Earth, containing over 1,000 galaxies—including about 150 large ones and numerous dwarfs—centered on prominent ellipticals such as Messier 84, Messier 86, and Messier 87, the latter hosting a supermassive black hole imaged in 2019.^[2] Located approximately 54 million light-years (16.5 megaparsecs) away, the Virgo Cluster dominates the supercluster's mass distribution and exerts significant gravitational influence, pulling nearby structures like the Local Group toward it at velocities of several hundred kilometers per second.^[4]^[5] The supercluster also includes secondary concentrations, such as the Fornax Cluster with approximately 60 large galaxies, highlighting its irregular, flattened morphology akin to a supergalactic plane.^[2]^[6] The Local Group, comprising the Milky Way, Andromeda, and about 50 other galaxies within a 3-million-light-year span, resides on the periphery of the Virgo Supercluster, underscoring humanity's position within this hierarchical cosmic architecture.^[1] Observations from telescopes like Hubble and ground-based surveys have mapped its extent, revealing it as part of even larger filaments in the cosmic web.^[4]

Introduction

Definition and Characteristics

The Virgo Supercluster, also known as the Local Supercluster, is a gravitationally bound large-scale structure in the universe consisting of approximately 100 galaxy groups and clusters that collectively contain an estimated 30,000 galaxies (including about 2,500 large galaxies and 25,000 dwarf galaxies).^[2] It is centered on the Virgo Cluster and incorporates the Milky Way's Local Group as one of its peripheral members.^[4] This supercluster represents a key example of the cosmic web's hierarchical organization, where galaxies aggregate into groups, which in turn form clusters, and these clusters link into superclusters. The structure spans a diameter of approximately 110 million light-years, or 33 megaparsecs, making it vastly larger than individual galaxy clusters but smaller than even greater filaments in the observable universe.^[7] Its total mass is estimated at about $1.5 \times 10^{15} solar masses (M_\odot), derived from dynamical analyses of member motions and gravitational influences.^[8] For comparison, the central Virgo Cluster contains only about 1,300 to 2,000 galaxies within a much smaller volume of roughly 2-3 megaparsecs in diameter, highlighting the scale difference between clusters and superclusters.^[9] The supercluster's mass is overwhelmingly dominated by dark matter, with a mass-to-light ratio of about 300, indicating that dark matter constitutes the vast majority of the total mass, with the remainder consisting of baryonic matter in the form of stars, gas, and the intracluster medium within its galaxy populations.^[10] This dark matter framework provides the gravitational binding that holds the disparate groups and clusters together, while the visible baryonic components contribute to only a small fraction of the overall luminosity and mass.^[11]

Historical Discovery

The early recognition of large-scale structures beyond the Local Group began with Edwin Hubble's observations in the 1930s, where he used Cepheid variable stars and other distance indicators to map galaxy distributions, revealing dense concentrations such as the Virgo Cluster as a gravitationally bound system of hundreds of galaxies distinct from the expanding universe.^[9] Hubble's cataloging efforts during this period established the Virgo region as a significant aggregation, setting the stage for understanding broader associations.^[12] The formal identification of the Virgo Supercluster emerged in the 1950s through systematic surveys of galaxy clusters. French-American astronomer Gérard de Vaucouleurs analyzed the spatial distribution of nearby galaxies brighter than magnitude 12.5 and proposed in 1953 the existence of a "Local Supergalaxy," a flattened structure centered on the Virgo Cluster and encompassing the Local Group, which he later termed the Local Supercluster (also known as the Virgo Supercluster due to its prominence in the Virgo constellation).^[13] Concurrently, George Abell's 1958 catalog of rich clusters from the Palomar Observatory Sky Survey identified over 2,700 clusters, highlighting the Virgo Cluster as a central hub within a larger aggregation of dozens of groups and clusters, while Fritz Zwicky's independent assessments of cluster distances reinforced the non-random alignment.^[14] Initial mass estimates for this structure, derived from luminosity and assumed mass-to-light ratios, placed it around $10^{14} solar masses, though these were revised upward in subsequent decades as more data became available. Key advancements in the 1970s came from redshift surveys that spectroscopically measured galaxy velocities, confirming the supercluster's gravitational cohesion. Surveys like the early Center for Astrophysics (CfA) efforts, initiated in the late 1970s, revealed coherent peculiar motions deviating from the Hubble flow, indicating the structure was dynamically bound rather than a projection effect, with velocities clustered around the Virgo Cluster's mean redshift of approximately 1,000 km/s. These Doppler shifts from redshift data were crucial in delineating the supercluster's boundaries, separating its members—typically within 1,000–2,000 km/s—from neighboring structures like the Coma Supercluster at higher redshifts around 7,000 km/s.^[11] In the 1980s, refinements by R. Brent Tully built on these foundations through detailed mapping of nearby galaxies. Tully's 1982 analysis of the Local Supercluster's three-dimensional distribution highlighted its filamentary extensions, such as chains linking the Virgo Cluster to outlying groups, providing a more nuanced view of its irregular, flattened morphology.

Physical Structure

Extent and Morphology

The Virgo Supercluster's core region, centered on the Virgo Cluster, spans approximately 16 Mpc in radius, encompassing the cluster and its immediate surroundings where gravitational binding dominates. Extended arms and filaments reach out such that the overall structure has a diameter of roughly 33 Mpc along the major axis and a volume on the order of 10^4 Mpc³. This spatial extent highlights the supercluster's role as a gravitationally bound entity within the local universe, contrasting with simpler spherical models often used for isolated clusters. Morphologically, the structure is distinctly non-spherical, featuring a flattened, disk-like or sheet-like geometry with an axial ratio of about 1:3.^[15] This flattening aligns with the Virgo Strand filament, an elongated backbone approximately 100 Mpc in length and 10 Mpc thick, embedding the supercluster within the cosmic web's filamentary network. The density distribution shows asymmetry, with the highest concentrations near the Virgo Cluster core, gradually tapering into sparser extensions toward neighboring regions like the Coma Supercluster.^[15] The supercluster's boundary is defined by the zero-velocity surface, the locus where internal gravitational attraction equals the expansion due to the Hubble flow, estimated at 16–17 Mpc from the center. This irregular, filamentary form exemplifies the large-scale structure of the universe, surrounded by underdense voids that underscore its position in the cosmic web.^[16] The Local Group resides near the periphery of this flattened expanse.

Major Components

The Virgo Supercluster's central hub is the Virgo Cluster, cataloged as Abell 1656, which anchors the structure with its dominant gravitational influence. Located at a distance of approximately 16.5 Mpc from Earth, the cluster has a virial mass of (6.3 \pm 0.9) \times 10^{14} \, M_\odot and encompasses more than 1,300 galaxies brighter than B_T = 12, supplemented by thousands of fainter dwarf galaxies.^[11] Within the Virgo Cluster, key subclusters include the W Cloud, a background structure at roughly twice the distance of the main cluster core and rich in early-type elliptical galaxies; the M Cloud, positioned to the southwest and dominated by late-type and dwarf galaxies; and the Southern Extension, a filamentary structure extending southward that serves as a bridge to more distant concentrations like those in the Centaurus region.^[11] Peripheral groups form the outer backbone of the supercluster, notably the Local Group—with a total mass of approximately $5 \times 10^{12} \, M_\odot and including the Milky Way and Andromeda galaxies—the Ursa Major groups, and the Canes Venatici Cloud, all loosely integrated into the overall assembly.^[17]^[18] The supercluster's mass is distributed such that roughly 40% resides in the Virgo Cluster, about 30% in interconnecting filaments and peripheral groups, and the remaining 30% in the intracluster medium and extended dark matter halos. These components are interconnected through weak gravitational ties, with typical separations of 5–20 Mpc between major elements, including filamentary links that enhance the overall cohesion.^[15]

Galaxy Population

Clusters and Groups

The Virgo Supercluster encompasses a diverse array of galaxy clusters and groups, reflecting varying degrees of gravitational binding and evolutionary stages. The central Virgo Cluster exemplifies an irregular morphology, marked by asymmetric distributions and ongoing mergers that contribute to its substructured appearance, including features like the NGC 4636 group.^[19] In total, the supercluster contains approximately 100 rich clusters, which form its denser gravitational aggregates.^[20] Loose galaxy groups, numbering around 50 within the supercluster, typically comprise 10 to 50 member galaxies and possess masses between $10^{12} and $10^{13} M_\odot. These groups often exhibit distinct properties, such as the M81 Group, where spiral galaxies predominate.^[18] Morphological classifications reveal a pronounced segregation: dense cluster cores host roughly 60% ellipticals and S0 galaxies, transitioning to about 40% spirals and irregulars in the less dense outskirts. Dwarf galaxies dominate numerically, accounting for over 90% of the galaxy population across these structures.^[21] Recent surveys, such as the Next Generation Virgo Cluster Survey (NGVS) as of 2024, have refined these distributions, confirming the prevalence of dwarfs.^[22] Evolutionary dynamics are underscored by ongoing infall of galaxies from adjacent voids, fostering cluster growth, with evidence of recent mergers or tidal distortions in approximately 10% of member galaxies.^[23]^[24] Galaxy surface densities display a steep gradient, plummeting from ~100 galaxies per Mpc² in the core regions to less than 1 galaxy per Mpc² at the supercluster's periphery.^[25]

Filaments and Walls

The Virgo Supercluster exhibits a filamentary structure that connects its denser galaxy clusters, with the Virgo Strand serving as the primary filament. This elongated feature spans several tens of Mpc in length, with a typical width of about 1-2 Mpc, and harbors roughly 20% of the supercluster's total galaxy population, predominantly in loose groups and isolated galaxies that trace the underlying density enhancements.^[26]^[27] Complementing these filaments are sheet-like wall structures, which represent flattened planes of galaxy distributions within the supercluster. These walls often border expansive underdense regions, emphasizing the supercluster's integration into the broader cosmic web.^[27] Galaxies within the Virgo Supercluster demonstrate preferential alignment along these filaments, reflecting the influence of tidal forces and gravitational infall. Adjacent voids, such as the Local Void, lie in close proximity to these structures, underscoring the stark contrast between the dense filamentary networks and the surrounding empty volumes. The mass distribution in these filaments constitutes about 25% of the Virgo Supercluster's total mass, with much of this inferred to be dark matter based on weak lensing measurements that detect subtle distortions in background light from foreground structures. These filaments primarily serve as tracers of dark matter concentrations, where baryonic matter in galaxies follows the gravitational potential wells.^[28] In terms of formation, the filaments and walls of the Virgo Supercluster originated from primordial density fluctuations in the early universe, amplified by gravitational instability to form the skeleton of the cosmic web. Over approximately 10 billion years, these structures have accreted diffuse matter through hierarchical merging and collapse, evolving into the observed configuration while preserving the initial anisotropy of the density field.^[29]

Kinematics and Dynamics

Internal Motions

Galaxies within the Virgo Supercluster exhibit peculiar velocities that deviate from the uniform Hubble expansion, with average magnitudes ranging from approximately 300 to 600 km/s. These deviations arise from gravitational interactions among the supercluster's components, causing galaxies to move relative to the cosmic flow. In particular, the Local Group experiences an infall velocity toward the Virgo Cluster of about 135 km/s, as determined from analyses of nearby galaxy redshifts. Velocity dispersion within the supercluster varies significantly by region, reflecting its hierarchical structure. In the dense core dominated by the Virgo Cluster, the dispersion reaches approximately 640 km/s, based on redshift surveys of member galaxies, while it decreases to around 200 km/s in the more sparse outskirts where loosely bound groups reside. These measurements, derived from large-scale spectroscopic datasets, highlight the transition from virialized motions in the center to more coherent infall patterns peripherally.^[30]^[21] Orbital dynamics in the Virgo Supercluster are described by hierarchical infall models, in which peripheral galaxy groups and filaments accrete onto the central Virgo Cluster. These models incorporate the virial theorem, where the velocity dispersion \sigma relates to the mass M and radius r of cluster-scale structures via \sigma^2 \approx GM/r, providing estimates of infall rates consistent with observed peculiar velocities. Such frameworks explain the ongoing assembly of the supercluster through gravitational collapse of substructures.^[31] Substructure motions further illustrate the dynamic environment, with mergers involving Virgo Cluster components occurring at relative speeds of approximately 500 km/s, as inferred from velocity offsets in subgroup analyses. Additionally, accretion along filaments feeds the supercluster at rates of 100-300 km/s, contributing to the growth of the central concentration.^[21] The timescales for these internal motions indicate an active evolutionary phase, with crossing times in the Virgo Cluster core estimated at 1-2 Gyr, suggesting the supercluster remains in the process of assembly rather than fully relaxed. This duration, calculated from typical velocities and structural scales, underscores the youth of the system relative to the universe's age.

External Influences and Motion

The Virgo Supercluster as a whole undergoes a bulk peculiar motion of approximately 600 km/s toward the Great Attractor, a massive overdensity situated in the direction of the Norma Cluster within the Hydra-Centaurus region.^[32] This large-scale flow represents the net gravitational response of the supercluster to external mass concentrations, contributing to the observed peculiar velocity of the Local Group at about 370 km/s relative to the cosmic microwave background (CMB). The direction of this motion aligns closely with the CMB dipole apex, providing direct evidence for the influence of nearby massive structures on our local cosmic neighborhood. A key driver of this bulk motion is the gravitational pull from the Shapley Supercluster, located at a recession velocity of roughly 10,000 km/s (corresponding to a redshift of z ≈ 0.048) but exerting significant attraction due to its exceptional density of galaxy clusters, estimated to contain over 20 times the mass of the Virgo Cluster.^[33] Despite its recession, the Shapley's overdensity dominates the peculiar velocity field beyond the Great Attractor, pulling the Virgo Supercluster and surrounding regions into a coherent flow pattern. The CMB dipole anisotropy, with an amplitude corresponding to a velocity of 370 km/s, further corroborates this large-scale motion, as the observed temperature variation across the sky matches the expected Doppler shift from our movement toward these attractors. Recent dynamical models utilizing the CosmicFlows-4 dataset, which compiles distances and velocities for over 56,000 galaxies, indicate that the Virgo Supercluster resides within a vast "basin of attraction" oriented toward the Shapley Concentration, encompassing a volume potentially ten times larger than previously defined structures like Laniakea. These 2024 analyses reveal an infall velocity of about 400 km/s into this basin, highlighting the hierarchical nature of gravitational influences on scales exceeding 100 Mpc. Over cosmic timescales, the accelerating expansion driven by dark energy is projected to counteract these gravitational bindings, leading to the gradual dispersal of supercluster-scale structures like Virgo within approximately 10^{10} years, as inferred from N-body simulations of large-scale structure evolution in a ΛCDM cosmology. Supporting observations include redshift-space distortions in galaxy surveys, which amplify peculiar velocities along the line of sight and reveal the coherent infall pattern across the supercluster, and proper motion measurements from the Gaia mission, which provide tangential velocity data for nearby galaxies supporting local flow patterns. These data underscore the dynamic interplay between local gravity and the global expansion, with the Virgo Supercluster's motion serving as a probe of the underlying matter distribution.

Cosmological Context

Relation to Laniakea and Larger Structures

The Virgo Supercluster forms a central component within the larger Laniakea Supercluster, which was identified in 2014 through mapping of galaxy peculiar velocities derived from distance indicators and redshift data.^[3] Laniakea encompasses the Virgo Supercluster as its core basin of attraction toward the Great Attractor, a massive overdensity influencing local galaxy flows, and spans approximately 520 million light-years in diameter, containing over 100,000 galaxies with a total mass of about $10^{17} solar masses.^[34] This structure integrates the previously defined Virgo, Hydra-Centaurus, and other nearby superclusters into a unified volume bounded by the zero-velocity surface where peculiar motions relative to the central attractor cease.^[35] In the broader hierarchical cosmic web, Laniakea represents one of roughly 10 million superclusters populating the observable universe, each embedded within filaments, walls, and voids on scales exceeding hundreds of millions of light-years.^[36] The Virgo Supercluster contributes approximately 1% of Laniakea's total mass, estimated at $10^{15} solar masses, highlighting its role as a dense but subordinate node within this larger assembly.^[4] Boundaries between the Virgo Supercluster and the encompassing Laniakea remain fuzzy, influenced by the accelerating expansion driven by dark energy, with the transition marked by an isovelocity surface at around 600 km/s where local gravitational inflows give way to Hubble flow dominance.^[3] Recent studies from 2024, utilizing advanced basin-of-attraction models from the CosmicFlows-4 catalog, indicate that Laniakea and the Virgo Supercluster may be embedded within an even grander structure centered on the Shapley Concentration, potentially expanding our local cosmic neighborhood by a factor of 10 in volume and challenging traditional isolated supercluster delineations.^[37] Additionally, 2025 cosmological simulations demonstrate that Laniakea is already undergoing structural tearing due to cosmic expansion, as its filaments and clusters are insufficiently bound against dark energy's repulsive effects, leading to gradual dispersal over billions of years.^[38] In this cosmic web analogy, the Virgo Supercluster serves as a local "neighborhood," while Laniakea functions as the encompassing "city," both ultimately part of vast, evolving metropolitan structures like the Shapley attractor.^[39]

Implications for Dark Matter and Energy

The dynamics of the Virgo Supercluster reveal a significant mass discrepancy, where gravitational effects imply a total mass far exceeding that accounted for by visible matter. Applying the virial theorem, the estimated virial mass for the supercluster's core region is on the order of $10^{15} M_\odot, derived from velocity dispersions \sigma \approx 700 km/s over a characteristic radius r \approx 1 Mpc using M = \sigma^2 r / G.^[40] This mass is dominated by dark matter, which constitutes approximately 85% of the total, as inferred from comparisons between luminous and dynamical mass estimates across member clusters and groups.^[41] In the cold dark matter (CDM) paradigm, this dark matter is primarily distributed in extended halos enveloping galaxy clusters, with intracluster dark matter concentrations confirmed through gravitational lensing observations of Virgo Cluster members.^[42] Additionally, diffuse dark matter in intergalactic filaments contributes to the supercluster's dark matter distribution, forming bridges between clusters as predicted by hierarchical structure formation models.^[43] Recent searches for signatures of dark matter decay in the Virgo region have yielded null results, providing stringent constraints on particle models. Observations with the High-Altitude Water Cherenkov (HAWC) Observatory, using over 2000 days of data, detected no excess gamma-ray emission attributable to decaying dark matter in the Virgo Cluster, limiting decay lifetimes and excluding certain models for particles with masses above 10 GeV in channels such as \bar{b}b and \mu^+\mu^-.^[44] These findings align with broader CDM expectations, where stable, non-interacting dark matter particles populate the supercluster's potential wells without radiative decay signals at detectable levels. The Virgo Supercluster's velocity field serves as a local laboratory for testing dark energy parameters within the \LambdaCDM framework, which predicts gradual dispersal of such structures due to accelerating expansion driven by \Omega_\Lambda \approx 0.7. Analysis of peculiar velocities and redshift distortions in the supercluster's galaxies constrains \Omega_\Lambda through comparisons between observed flows and model predictions, confirming consistency with cosmic microwave background (CMB) values.^[45] Recent 2025 N-body simulations of the Virgo environment achieve redshift predictions accurate to 0.2-0.5%, validating \LambdaCDM's handling of dark energy effects on large-scale dynamics while highlighting minor deviations in filamentary infall patterns.^[46] Furthermore, Cepheid variable stars in Virgo member galaxies, such as those in M100, yield a local Hubble constant H_0 \approx 70 km/s/Mpc, contributing to calibration of the distance ladder but revealing tensions with CMB-derived H_0 \approx 67 km/s/Mpc, potentially linked to large-scale flows influencing the supercluster.^[47] Projections of the supercluster's evolution under \LambdaCDM indicate it remains gravitationally bound until approximately z \approx 0.5, after which dark energy-driven expansion dominates, isolating internal motions per the Friedmann equation \dot{a}/a = H_0 \sqrt{\Omega_m / a^3 + \Omega_\Lambda}. Beyond this epoch, the structure disperses without further collapse, evolving into a static "island universe" amid cosmic acceleration.^[48]

Observations

Survey Methods

The study of the Virgo Supercluster relies on a range of observational techniques to map its three-dimensional structure and internal dynamics, primarily through redshift spectroscopy, multi-wavelength imaging, and astrometric measurements. Early efforts before the 2000s utilized photographic plates for wide-field optical surveys, enabling the identification of galaxy positions and morphologies across large areas of the sky. For instance, the classical Virgo Cluster Catalog compiled data on approximately 1,300 member galaxies using blue-sensitive photographic plates taken with the du Pont 2.5-m telescope, providing foundational optical imaging for the cluster core.^[49] These methods laid the groundwork for subsequent spectroscopic follow-up but were limited by low resolution and sensitivity to faint objects. Redshift surveys employing spectroscopic techniques have been crucial for determining radial velocities and reconstructing the 3D distribution of galaxies within the supercluster. Instruments like the 2dF spectrograph on the Anglo-Australian Telescope and the Sloan Digital Sky Survey (SDSS) fiber spectrographs have measured redshifts for thousands of galaxies, revealing filamentary structures and group associations out to the supercluster's extent. Specifically, these surveys have mapped galaxies in the Virgo Supercluster volume, allowing inference of peculiar velocities and large-scale flows through the Doppler shift of emission lines such as Hα.^[50] Imaging techniques across multiple wavelengths complement spectroscopy by tracing stellar populations, gas, and dark matter distributions. In the optical regime, modern surveys like the Extended Virgo Cluster Catalog, based on SDSS multi-band imaging, expanded membership lists to about 1,589 galaxies over 725 square degrees, improving photometric redshifts and morphological classifications compared to earlier plate-based efforts. X-ray observations with the Chandra X-ray Observatory target the hot intracluster medium (ICM), where diffuse emission from temperatures around 2 keV traces gravitational potential wells and dark matter halos; archival Chandra data of early-type galaxies in the Virgo Cluster reveal extended hot gas coronae with luminosities indicating ongoing environmental interactions.^[51]^[52] Weak gravitational lensing, using high-resolution imaging from the Hubble Space Telescope (HST) and Subaru Telescope, distorts background galaxy shapes to produce mass maps; HST Advanced Camera for Surveys data on Virgo fields, combined with Subaru Hyper Suprime-Cam shear measurements, have delineated subhalo structures and total mass profiles without relying on luminous tracers. Multi-wavelength approaches enhance coverage of obscured or diffuse components. Radio observations map neutral hydrogen (HI) in spiral galaxies via 21-cm emission, with single-dish telescopes like Arecibo providing major-axis profiles for over 140 Virgo spirals to assess gas stripping and kinematics. Infrared imaging with the Spitzer Space Telescope probes dust content and star formation; IRAC 3.6–4.5 μm observations of the Virgo core reveal low-surface-brightness features in intracluster light, indicating tidal stripping from satellites. Recent astrometric data from Gaia Data Release 3 (DR3) measure proper motions for approximately 1,000 stars in nearby Virgo members, enabling tangential velocity estimates and dynamical modeling of cluster infall. Post-2010 advancements include integral field units like the Multi-Unit Spectroscopic Explorer (MUSE) on the Very Large Telescope, which provide spatially resolved spectroscopy for kinematics in ram-pressure-stripped galaxies, revealing velocity gradients and ionization states in the ICM interface.^[53]^[54]^[55]^[56] Observing the Virgo Supercluster at a distance of about 16 Mpc presents inherent challenges, including angular resolution limits that blur substructure details—requiring space-based telescopes like HST for arcsecond-scale imaging—and foreground interference from the Milky Way, such as stellar crowding and diffuse emission in low Galactic latitudes. Dust obscuration along the Galactic plane further complicates optical and near-infrared surveys in the supercluster's southern extensions, necessitating multi-wavelength strategies to mitigate extinction effects up to A_V ≈ 1 mag in affected fields.^[57]

Key Datasets and Maps

The Virgo Cluster Catalog (VCC), published by Binggeli et al. in 1985, compiles 2,096 galaxies within the core Virgo Cluster region, providing a benchmark for morphological and photometric classifications based on photographic plate surveys. This dataset emphasizes dwarf and giant ellipticals, enabling early analyses of the cluster's luminosity function and spatial distribution. Building on the VCC, the Extended Virgo Cluster Catalog (EVCC) by Kim et al. in 2014 catalogs 1,589 galaxies over a broader area of 725 square degrees, derived from Sloan Digital Sky Survey Data Release 7 imaging and spectroscopy.^[51] The EVCC enhances depth and uniformity, facilitating comparisons of galaxy properties across the supercluster's transition zones.^[51] Subsets within the NASA/IPAC Extragalactic Database (NED) aggregate multi-wavelength observations of Virgo Supercluster galaxies, including redshifts from over 10,000 objects and cross-matches with radio and X-ray sources, supporting integrated studies of the structure.^[58] Pioneering 3D maps from Tully's 1980s redshift surveys, such as the 1982 analysis of the Local Supercluster, utilized optical spectroscopy to plot galaxy positions in velocity space, outlining the ellipsoidal envelope enclosing the Virgo Cluster and adjacent groups. The 2014 Laniakea flow map by Tully et al. applied a Wiener filter to peculiar velocity catalogs, reconstructing density and velocity fields to visualize the Virgo Supercluster's integration into the larger Laniakea basin, with divergences marking basin boundaries.^[59] The Cosmic Large-Scale Structure in X-rays (CLASSIX) survey, detailed by Schuecker et al. in 2022, identifies eight superclusters from ROSAT All-Sky Survey data, including the Virgo region with its X-ray luminous clusters tracing filamentary connections.^[60] All-sky projections, such as those in Tully et al. 2014, illustrate the Virgo Supercluster as a flattened disk with a major axis of about 110 million light-years, emphasizing its oblate geometry in galactic coordinates.^[59] Density contour plots from EVCC and NED data reveal galaxies concentrated in core volumes spanning tens of megaparsecs, highlighting overdense ridges amid voids.^[51]^[58] These datasets and maps are publicly released via the NASA/IPAC Extragalactic Database (NED) and SIMBAD astronomical database.^[58]

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Sep 3, 2014 · This Laniakea Supercluster is 500 million light-years in diameter and contains the mass of 1017 (a hundred quadrillion) suns in 100,000 galaxies ...
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Newly Identified Galactic Supercluster Is Home to the Milky Way
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The Universe within 14 billion Light Years - The Visible Universe
Number of superclusters in the visible universe = 10 million. * Number of galaxy groups in the visible universe = 25 billion. * Number of large galaxies in ...
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UH astronomers: Our cosmic neighborhood may be 10x larger
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Laniakea, our home supercluster, is already being torn apart
Jul 31, 2025 · But the most dominant nearby structure is the Virgo Cluster of galaxies, containing more than a thousand galaxies comparable in size/mass to the ...
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The Milky Way might be part of an even larger structure than Laniakea
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[PDF] Extragalactic dark matter and direct detection experiments - arXiv
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[2309.03973] Search for Decaying Dark Matter in the Virgo Cluster ...
Sep 7, 2023 · Using 2141 days of data, we search for gamma-ray emission from the Virgo cluster, assuming well-motivated dark matter sub-structure models. Our ...
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Future evolution of bound superclusters in an accelerating Universe
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(PDF) Testing No-Dark-Matter Claims with a 1,000-Galaxy Virgo ...
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[PDF] 1 THE DISTANCE TO THE VIRGO CLUSTER FROM A ... - arXiv
distances to the five Virgo cluster galaxies with Cepheids. These are NGC ... Virgo cluster elliptical galaxies of m - M = 31.47 + 0.25, Ho ~ 70. They ...
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Studies of the Virgo Cluster. II - A catalog of 2096 galaxies in the ...
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Superclusters of galaxies from the 2dF redshift survey
Modern redshift surveys make it possible to investigate not only these classical systems of galaxies, but also galaxy systems of inter- mediate sizes and ...
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THE EXTENDED VIRGO CLUSTER CATALOG - IOPscience
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X-Ray Constraints on the Hot Gas Content of Early-type Galaxies in ...
We present a systematic study of the diffuse hot gas around early-type galaxies (ETGs) residing in the Virgo cluster, based on archival Chandra observations.
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H i Observations in the Virgo Cluster Area. III. All ``Member'' Spirals
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SPITZER/IRAC LOW SURFACE BRIGHTNESS OBSERVATIONS OF ...
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MUSE sneaks a peek at extreme ram-pressure stripping events
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Superclusters of galaxies in the 2dF redshift survey
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NASA/IPAC Extragalactic Database: Home
Mosaic of JWST/NIRCam data covering the Hubble Deep Field region from the publication describing data release 3 of JWST Advanced Deep Extragalactic Survey ( ...Classic Home Page · Database · Articles about NED · Data SetsMissing: Virgo Supercluster IR
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[1409.0880] The Laniakea supercluster of galaxies - arXiv
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The case of the missing high proper motion stars in GAIA DR3
The large proper motions of these stars, along with estimated photometric distances, strongly suggest that most of these "missing" stars are relatively nearby ...Missing: scale flow Supercluster
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The Cosmic Large-Scale Structure in X-rays (CLASSIX) cluster ...
May 16, 2022 · With a friends-to-friends algorithm, we find eight superclusters with a cluster overdensity ratio of at least two with five or more galaxy group ...Missing: DESI 2024 filament
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J-Virgo: A JWST Treasury Survey of the Virgo Cluster - NASA ADS
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