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Cosmos Redshift 7
Cosmos Redshift 7
Cosmos Redshift 7
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Cosmos Redshift 7
Artist's impression of CR7
Observation data (Reionization epoch)
ConstellationSextans
Right ascension10h 00m 58.005s[1]
Declination+01° 48′ 15.251″[1]
Redshift6.604[1]
Distance12.9 billion light-years[2]
Characteristics
TypeLyman-alpha emitter[1]
Notable featuresGalaxy Cosmos Redshift 7 is reported to be three times brighter than the brightest distant galaxy known up to the time of its discovery and to contain some of the earliest first stars that produced the chemical elements needed for the later formation of planets and life as it is known.[1]
Other designations
COSMOS Redshift 7; Galaxy Cosmos Redshift 7; Galaxy CR7; CR7, SMD2015 CR7

Cosmos Redshift 7 (also known as COSMOS Redshift 7, Galaxy Cosmos Redshift 7, Galaxy CR7 or CR7) is a high-redshift Lyman-alpha emitter galaxy. At a redshift z = 6.6,[1] the galaxy is observed as it was about 800 million years after the Big Bang, during the epoch of reionisation.[1] With a light travel time of 12.9 billion years, it is one of the oldest, most distant galaxies known.

CR7 shows some of the expected signatures of Population III stars i.e. the first generation of stars produced during early galaxy formation.[1][2][3][4][5] These signatures were detected in a bright pocket of blue stars; the rest of the galaxy contains redder Population II stars.[3] However, recent studies show no evidence for population III stars in CR7.[6]

Description

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Galaxy Cosmos Redshift 7 contains old Population II (metal-poor) and possibly Population III (stars with extremely poor metallicity), according to astronomers,[1][2] and is three times brighter than the brightest distant galaxies (redshift, z > 6)[1][7] detected up to the time of its discovery.[3][5]

Discovery

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Astronomers led by David Sobral, a Reader in Astrophysics at the University of Lancaster, used the Very Large Telescope (VLT) at the European Southern Observatory—with help from the W. M. Keck Observatory, Subaru Telescope and the NASA/ESA Hubble Space Telescope—made the discovery.[5] The research team included members of the University of California, Riverside,[5] University of Geneva, University of Leiden and University of Lisbon.[1] The name of the galaxy (Cosmos Redshift 7 Galaxy) was inspired by football player Cristiano Ronaldo, also popularly known as CR7.[3][8][9][10]

See also

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References

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Cosmos Redshift 7

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Cosmos Redshift 7 (CR7) is a high-redshift Lyman-α emitting galaxy in the COSMOS survey field at a spectroscopic redshift of z = 6.604, corresponding to a lookback time of approximately 800 million years after the Big Bang. It is the brightest known Lyα emitter at this epoch, with a line luminosity of L(Lyα) = 1044.0 erg s−1, and features prominent He II λ1640 emission at L(He II) = 1043.3 erg s−1, which initially suggested a substantial contribution from metal-poor, Population III-like stars in a low-metallicity environment. CR7 was discovered in 2015 through a wide-field (~5 deg2) narrow-band survey for Lyα emitters at z ≈ 6.6 conducted with the Subaru Telescope's Hyper Suprime-Cam, marking it as three times brighter than the previous record holder at this . Spectroscopic followed using the ESO Very Large Telescope's SINFONI and FORS2 instruments, revealing a narrow He II line (FWHM = 120 km s−1) extended over ~10 kpc with a double-peaked profile indicative of outflows or a diffuse , and no evidence for an in initial observations, though recent JWST data indicate tentative AGN activity in CR7-A. The galaxy's rest-frame UV continuum is also detected, with a He II/UV ratio of 1.5%, consistent with models of young, metal-poor stellar populations. Follow-up observations have refined our understanding of CR7's composition and dynamics. ALMA imaging in 2017 detected [C II] λ158 μm emission tracing metals across multiple components but found no associated dust continuum, implying a young, low-dust system with ionized gas rather than a pure Population III galaxy. imaging resolved CR7 into three UV-bright clumps separated by ~5–10 kpc, suggesting a merging or interacting system. More recently, JWST/NIRSpec integral field , part of the GA-NIFS program, has dissected CR7's substructures in 2024–2025, identifying three main components (CR7-A, CR7-B, CR7-C) connected by extended [O III] λ5007 emission and a satellite clump (CR7-D) at ~6.8 kpc, with evidence of tidal interactions and gas inflows. Key properties include a dynamical mass of ~2.4 × 1010 M for CR7-A, total star formation rate of ~30 M yr−1 (log SFR = 1.5) based on Hα, and average gas-phase metallicities of ~0.2 Z (12 + log(O/H) ≈ 8.0), with spatial variations indicating enrichment through mergers. Kinematic maps show velocity gradients of -200 to 0 km s−1 and dispersions suggesting rotation or inflows, while the star formation history points to a peak ~200 Myr prior and recent bursts. Located in the constellation Sextans, CR7 provides critical insights into early galaxy assembly, reionization, and the transition from primordial to metal-enriched star formation during the cosmic dawn.

Overview

General Description

Cosmos Redshift 7 (CR7) is a high-redshift Lyman-α emitter located in the early during the of , a period when the first stars and galaxies began ionizing the neutral hydrogen fog that permeated space. Lyman-α emitters are galaxies distinguished by their intense emission of Lyman-α photons, which are light from the recombination of electrons and protons in hydrogen atoms, making them detectable even at vast distances through narrowband filters tuned to the redshifted wavelength. CR7 stands out as an exceptionally luminous example of such a , observed as it existed approximately 800 million years after the . In terms of brightness, CR7 is three times more luminous in the than any other known at redshifts greater than 6, with a Lyman-α luminosity reaching about 10^{43.9} erg/s, setting it apart as the most radiant object identified from this formative era. This extraordinary suggests intense activity, providing a window into the processes that shaped the shortly after its infancy. The exhibits an irregular and clumpy morphology, characterized by multiple spatially separated components observed in imaging, which is typical of early galaxy formation where mergers and rapid assembly lead to fragmented structures rather than smooth disks. These clumps indicate ongoing hierarchical buildup, reflecting the turbulent conditions of the at this time.

Location and Coordinates

Cosmos Redshift 7 (CR7) is situated in the constellation . Its precise equatorial coordinates in the J2000 epoch are 10h00m58.005s10^{\rm h}00^{\rm m}58.005^{\rm s} and +014815.251+01^\circ 48' 15.251''. These coordinates place CR7 within the survey field, a 2 patch of sky centered at approximately 10h00m28.6s10^{\rm h}00^{\rm m}28.6^{\rm s} and +021221.7+02^\circ 12' 21.7'', selected for its low foreground extinction and suitability for multiwavelength extragalactic research. The field, observed extensively by telescopes including the and ground-based facilities like Subaru and VLT, enables detailed studies of distant galaxies like CR7 through its deep imaging and spectroscopy.

Discovery and Initial Observations

Detection Process

Cosmos Redshift 7 (CR7) was discovered in as part of a wide-field survey targeting Lyman-α emitters at redshift z ≈ 6.6, conducted over approximately 5 square degrees in the field. The survey utilized the equipped with the Hyper Suprime-Cam instrument and the NB921 filter, centered at 9210 Å, to detect strong Lyman-α emission lines from high-redshift sources while minimizing continuum contamination. This method exploits the fact that Lyman-α emission at z = 6.6 falls within the NB921 bandpass at about 50% transmission, allowing for the identification of bright, line-emitting galaxies against the epoch. CR7 emerged as one of the two most luminous Lyman-α candidates in the survey, exhibiting exceptional brightness and spatial extent (~3 arcseconds, or roughly 16 kpc at that ) in the Subaru . To refine the photometric selection and rule out lower- interlopers, deeper broadband was performed using facilities such as the (VLT) with FORS2 in the z-band and the W. M. Keck Observatory, complemented by near-infrared data from the UltraVISTA survey and . These multi-wavelength observations confirmed CR7's high- nature through a sharp color break between the dropout in rest-frame bands and detection in longer wavelengths, isolating it as a prime candidate for follow-up. The galaxy was named CR7, an abbreviation for " Redshift 7," reflecting its location in the survey field and approximate ; the moniker coincidentally aligns with the nickname of athlete . Led by David Sobral of the and Leiden Observatory, along with collaborators including Jorryt Matthee, the detection highlighted the efficacy of narrowband Lyman-α surveys in uncovering rare, luminous objects from the early universe.

Spectroscopic Confirmation

Following the initial detection of CR7 as a bright Lyman-α emitter candidate in imaging surveys, spectroscopic observations were conducted to confirm its high-redshift nature and properties. These efforts utilized the X-SHOOTER and SINFONI instruments on the (VLT) at Cerro Paranal Observatory, along with the DEIMOS spectrograph on the Keck II telescope at [Mauna Kea Observatory](/page/Mauna Kea Observatory). The observations took place during campaigns spanning late 2014 to early 2015, with specific nights including December 28, 2014, for X-SHOOTER on VLT, and multiple sessions in January through April 2015 using SINFONI and DEIMOS. The DEIMOS spectrum, in particular, achieved confirmation of the Lyman-α emission in just 15 minutes of integration time despite CR7's extreme distance. The primary spectral feature identified was a strong Lyman-α emission line at an observed wavelength of approximately 9244 , corresponding to a of z = 6.604 ± 0.001, with a (FWHM) of 266 ± 15 km/s. Data reduction and analysis involved standard pipeline processing for each instrument, followed by Gaussian profile fitting to the emission lines to measure their strengths, widths, and positions. The spectra revealed intense emission associated with multiple spatially resolved clumps within CR7, as cross-correlated with (WFC3) imaging; clump A dominated the Lyman-α and UV flux, while clumps B and C contributed to the overall structure, separated by about 5 kpc. This multi-component analysis confirmed CR7 as a Lyman-α emitter at high , with the exceeding 50 in the rest frame.

Physical Properties

Redshift and Distance

Cosmos Redshift 7 (CR7) has a spectroscopically confirmed of z=6.604z = 6.604, determined through observations of its emission lines using the . This high places CR7 among the most distant galaxies observed, reflecting the significant since the light was emitted. The arises from the cosmological expansion, which stretches the emission line from its rest-frame wavelength of 121.6 nm to an observed wavelength of approximately 0.925 μm. This shift indicates that the light from CR7 has traveled for a look-back time of 12.9 billion years, corresponding to an era when the was about 800 million years old. In the standard Λ\LambdaCDM cosmology, this yields a comoving of approximately 25.4 billion light-years to CR7, providing a measure of its present-day separation from adjusted for expansion. These metrics highlight CR7's position in the early , offering a glimpse into conditions shortly after the .

Size, Luminosity, and Mass

Cosmos Redshift 7 (CR7) exhibits a rest-frame UV absolute magnitude of M150022.5M_{1500} \approx -22.5, derived from its rest-frame UV continuum at 1500 Å, making it one of the brightest known galaxies at redshifts z>6z > 6. This magnitude corresponds to an ultraviolet luminosity of approximately 3×1012L3 \times 10^{12} L_\odot, measured through near-infrared photometry in the Y, H, and K bands using ground-based telescopes, with the value reflecting the integrated emission from its star-forming components after correcting for the high-redshift dimming. The physical size of CR7 spans approximately 16 kpc in its Lyα-emitting region, as determined from the spatial extent observed in narrow-band imaging and spectroscopic data. imaging resolved CR7 into three UV-bright clumps (CR7-A, CR7-B, CR7-C) separated by ~5–10 kpc, with an additional satellite clump (CR7-D) at ~6.8 kpc, suggesting a merging or interacting . Recent JWST/NIRSpec observations confirm these substructures connected by extended [O III] λ5007 emission, with an effective radius of ~0.92 kpc for CR7-A, indicating a compact, clumpy morphology typical of early starburst systems, with the overall structure corrected for cosmological to yield the proper physical scale. Dynamical mass estimates for CR7 indicate ~2.4 × 10^{10} M_⊙ for the main component CR7-A, derived from kinematic modeling of velocity dispersions (~124 km s^{-1}). Stellar mass estimates from (SED) fitting yield ~5 × 10^9 M_⊙ for CR7-A, ~8 × 10^8 M_⊙ for CR7-B, and ~1.3 × 10^9 M_⊙ for CR7-C, constrained by rest-frame UV to NIR photometry and assumptions about young, low-metallicity stellar populations. Earlier SED modeling from 2015 suggested a total around 1.6 × 10^{10} M_⊙, but recent data favor lower values dominated by the resolved components without a significant Population III contribution. The rate () in CR7 is estimated at ~55 M_⊙ yr^{-1} for CR7-A based on Hα emission over the last 10 Myr, with contributions of ~5 M_⊙ yr^{-1} from CR7-B and ~7 M_⊙ yr^{-1} from CR7-C, for a system total of ~67 M_⊙ yr^{-1}. These rates are derived from assuming a and account for a bursty history peaking ~200 Myr prior, providing a tracer of recent unobscured activity. Earlier UV-based estimates suggested 25–100 M_⊙ yr^{-1}, but refines this to reflect spatial variations and inflows.

Stellar Composition

The stellar composition of Cosmos Redshift 7 (CR7) consists of young, metal-poor Population II across its multiple components, consistent with a system undergoing mergers in the early . These contribute to the galaxy's observed luminosity primarily through recent starburst episodes involving low-mass, high-ionization sources. Initial 2015 observations suggested the possibility of Population III stars—first-generation, metal-free stars formed from primordial gas—based on the detection of a strong, narrow He II λ1640 emission line with an of approximately 80 Å. This feature, along with the absence of metal lines in the spectrum, aligned with theoretical predictions for massive Population III stars producing hard radiation capable of ionizing helium. The hypothesis posited that such stars could dominate the rest-frame continuum and nebular emission in CR7. Subsequent analysis in 2017 found no conclusive evidence for Population III stars, as the He II line was measured to be weaker (equivalent width of 40 ± 30 Å) and the galaxy's infrared colors were inconsistent with metal-free stellar models. Recent JWST spectroscopy confirms a low-metallicity stellar population with enhanced ionization, driven by young starbursts at average gas-phase metallicities of ~0.2 Z_⊙ (12 + log(O/H) ≈ 8.0) for CR7-A, varying spatially from ~0.12 Z_⊙ in CR7-B to ~0.29 Z_⊙ in CR7-C, indicating enrichment through tidal interactions and gas inflows. This composition is further evidenced by strong [O III] emission lines indicating high-ionization conditions in a metal-poor environment. These estimates reflect limited enrichment from previous stellar generations, aligning with the observed spectral features and supporting models of rapid during the post- era.

Scientific Significance

Role in Reionization

The of , spanning redshifts z6z \approx 6–$10$, represents a pivotal phase in cosmic history approximately 400–900 million years after the , during which the first generations of stars and galaxies emitted ultraviolet photons that progressively ionized the pervasive neutral in the intergalactic medium, transitioning the from an opaque to a transparent state for . This process is inferred to have been patchy and extended, with ionized regions expanding around luminous sources amid lingering neutral patches. Cosmos Redshift 7 (CR7), spectroscopically confirmed at z=6.604z = 6.604, occupies a position near the end of this , offering a critical snapshot of the transition as approached completion around z6z \sim 6. Its luminosity of 1044.010^{44.0} erg s1^{-1} indicates substantial production of ionizing photons, potentially capable of carving out local ionized volumes that contribute to the broader effort. The galaxy's rest-frame equivalent width of 100\approx 100 Å, based on 2020 observations, corresponds to a Lyα escape fraction of 3.4%\approx 3.4\% as measured in 2025, suggesting moderate transmission facilitated by outflows in its merging system rather than exceptionally high escape. Spectral analysis of CR7 reveals minimal absorption from neutral , with a detectable continuum visible at rest-frame wavelengths of 916–1017 Å blueward of , signifying low and transmission consistent with an ionized intergalactic environment. This low neutral column density points to the presence of an ionized bubble enveloping the galaxy, with an inferred spatial extent of approximately 16 kpc, likely self-generated by CR7's intense radiation field and indicative of its role in locally driving dynamics. Recent JWST observations reveal extended [O III] emission connecting multiple clumps, with velocity gradients of -200 to 0 km s1^{-1} suggesting inflows or rotation that enhance ionizing photon escape and contribute to patchy during cosmic dawn. Such features underscore CR7 as a luminous participant in the late stages of , where bright, merging sources like it accelerated the ionization of residual neutral .

Evidence for Population III Stars

The detection of a strong He II λ1640 emission line in CR7, with an equivalent width of approximately 180 Å, provided initial evidence for the presence of metal-free Population III (Pop III) stars in 2015. This line arises from high-energy ultraviolet radiation produced by massive, hot stars lacking metals, which ionize helium more efficiently than hydrogen, a signature expected from Pop III stars with initial masses exceeding 100 solar masses. The spectrum also showed a spatial separation, with the He II emission originating from a compact region distinct from the broader Lyman-α emission, suggesting a localized burst of Pop III star formation within CR7. Subsequent analysis in 2017 challenged this interpretation, attributing the He II line to Wolf-Rayet (WR) stars in a metal-poor Population II (Pop II) environment rather than pure Pop III stars. The line's narrow width ( of about 200 km/s) and lack of associated broad C IV or other metal lines indicated lower-ionization processes typical of WR winds in galaxies with modest (Z ≈ 0.1 Z⊙), not the extreme conditions required for Pop III. Models fitting the observed spectrum favored a young, massive with some enrichment, ruling out a dominant Pop III component that would produce broader, more intense He II emission. JWST/NIRSpec observations in 2024–2025 confirmed the absence of Pop III signatures, detecting no He II λ1640 emission (upper limit ≤0.3 × 10^{-18} erg s^{-1} cm^{-2}) and measuring average gas-phase metallicities of ~0.2 Z_⊙ (12 + log(O/H) ≈ 8.0, with variations across components), consistent with metal-poor Pop II stars in a young, low-dust merger system. The history indicates a peak ~200 Myr prior and recent bursts driven by tidal interactions, highlighting CR7's role in the transition to metal-enriched without primordial contributions. Distinguishing Pop III signatures at high redshifts like z ≈ 6.6 remains challenging due to the faintness of these early galaxies and potential blending of spectral lines with foreground interlopers or sky emission. He II detection is particularly prone to contamination from active galactic nuclei or shock-excited gas, and the absence of metal lines alone cannot reliably confirm metal-free stars, as low-metallicity Pop II systems can mimic similar spectra. High-redshift observations are further limited by the small sizes of Pop III host halos (typically <100 pc), making resolved spectroscopy difficult with current ground-based telescopes.

Comparative Context

Comparison to Other High-Redshift Galaxies

Cosmos Redshift 7 (CR7) stands out among high-redshift galaxies due to its exceptional ultraviolet (UV) continuum brightness. With an absolute UV magnitude of MUV21.9M_{\rm UV} \approx -21.9, CR7 is brighter than the lensed galaxy A1689-zD1 at z=7.5z = 7.5, which has an intrinsic MUV18M_{\rm UV} \approx -18 after correcting for magnification. Similarly, CR7's UV luminosity exceeds that of GN-z11 at z=10.6z = 10.6 (MUV=21.6M_{\rm UV} = -21.6), highlighting its prominence despite the higher redshift of the latter. This brightness places CR7 approximately three times more luminous in the UV than , the prior record holder among z>6z > 6 emitters. Recent JWST observations confirm CR7 and as similar blue, metal- and dust-poor major merger systems. In terms of morphology, CR7 exhibits a more extended and clumpy structure than the typically compact high-redshift galaxies identified in (HUDF) surveys. Its overall size spans approximately 16 kpc, resolved into three distinct clumps separated by ~5–10 kpc, contrasting with the sub-kpc half-light radii (typically re0.51r_e \sim 0.5-1 kpc) of most z67z \sim 6-7 galaxies in HUDF data. For instance, displays an extremely compact effective radius of about 0.15 kpc, underscoring CR7's unusually diffuse and multi-component nature at similar epochs. Recent JWST data indicate that clumpy morphologies with multiple subcomponents are common in ~70% of bright galaxies at z ∼ 7, often linked to merger-induced starbursts. CR7's emission further distinguishes it, with a higher implied escape fraction than the average for z7z \sim 7 galaxies, where typical values range from 0.02 to 0.1. The galaxy's observed luminosity of 1044.010^{44.0} erg s1^{-1} and suggest an intrinsic escape fraction potentially greater than 0.5, facilitating its detection amid the neutral intergalactic medium. This contrasts with lower escape fractions in compact sources like those in HUDF surveys, where is often suppressed. Low dust content in CR7 supports a high escape fraction. Regarding evolutionary stage, CR7 appears more advanced and massive than typical progenitors of z=67z = 6-7 galaxies. Its total is estimated at ~10^9 across components, exceeding the median masses of 10^8-10^9 for contemporaneous UV-selected galaxies. This elevated and , along with a dynamical of ~2.4 × 10^{10} for the main component, indicate CR7 as a rare, rapidly evolving system compared to the smaller, less luminous objects dominating early populations.

Implications for Early Universe Models

The discovery of CR7, with its multiple clumpy components separated by ~5–10 kpc, provides strong support for hierarchical merging models of galaxy formation in the early . These structures suggest ongoing mergers, enabling rapid growth of massive galaxies at high redshifts through the assembly of smaller subunits rather than monolithic . Such clumpy configurations align with simulations predicting that early galaxies form via frequent mergers in dense environments, facilitating the buildup of within the first billion years after the . Recent JWST observations reveal tidal interactions and gas inflows connecting the components. CR7's exceptional , reaching 10^{44.0} erg s^{-1} in Lyα emission and extending over ~16 kpc, has significant implications for models. This brightness indicates that CR7 could ionize large local bubbles, contributing substantially to the patchy process during the of . Theoretical models incorporating such luminous sources suggest that fewer bright galaxies are required to achieve full compared to scenarios relying solely on more numerous, fainter objects, thereby refining estimates of the sources driving cosmic . The low-metallicity signatures in CR7, including strong He II λ1640 emission with an of ~80 , impose tight constraints on feedback mechanisms from massive stars. However, detections of [C II] and [O III] lines indicate average gas-phase metallicities of ~0.2 Z_⊙, with spatial variations from merger-driven enrichment. Models indicate that feedback from such stars in low-metallicity environments limits pristine star-forming regions, promoting bursts before full metal enrichment, which helps explain the scarcity of primordial signatures at high redshifts. CR7's properties as a massive at z ≈ 6.6 are broadly consistent with ΛCDM cosmology, which predicts the existence of rare, bright objects formed through efficient baryonic accretion onto halos. However, its rapid assembly challenges some hydrodynamical simulations that struggle to reproduce such early massive structures without invoking enhanced mechanisms like feedback to concentrate gas and trigger bursty . These findings underscore the need for refined simulations incorporating radiative processes to better match the observed diversity and timescales of high-redshift growth.
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