An ultra-high-resolution map of (dark) matter

Diana Scognamiglio; Gavin Leroy; David Harvey; Richard Massey; Jason Rhodes; Hollis B. Akins; Malte Brinch; Edward Berman; Caitlin M. Casey; Nicole E. Drakos; Andreas L. Faisst; Maximilien Franco; Leo W.H. Fung; Ghassem Gozaliasl; Qiuhan He; Hossein Hatamnia; Eric Huff; Natalie B. Hogg; Olivier Ilbert; Jeyhan S. Kartaltepe; Anton M. Koekemoer; Shouwen Jin; Erini Lambrides; Alexie Leauthaud; Zane D. Lentz; Daizhong Liu; Guillaume Mahler; Claudia Maraston; Crystal L. Martin; Jacqueline McCleary; James Nightingale; Bahram Mobasher; Louise Paquereau; Sandrine Pires; Brant E. Robertson; David B. Sanders; Claudia Scarlata; Marko Shuntov; Greta Toni; Maximilian von Wietersheim-Kramsta; John R. Weaver

doi:10.1038/s41550-025-02763-9

An ultra-high-resolution map of (dark) matter

Diana Scognamiglio^*
, Gavin Leroy
, David Harvey
, Richard Massey
, Jason Rhodes
, Hollis B. Akins
, Malte Brinch
, Edward Berman
, Caitlin M. Casey
, Nicole E. Drakos
, Andreas L. Faisst
, Maximilien Franco
, Leo W.H. Fung
, Ghassem Gozaliasl
, Qiuhan He
, Hossein Hatamnia
, Eric Huff
, Natalie B. Hogg
, Olivier Ilbert
, Jeyhan S. Kartaltepe

Anton M. Koekemoer, Shouwen Jin, Erini Lambrides, Alexie Leauthaud, Zane D. Lentz, Daizhong Liu, Guillaume Mahler, Claudia Maraston, Crystal L. Martin, Jacqueline McCleary, James Nightingale, Bahram Mobasher, Louise Paquereau, Sandrine Pires, Brant E. Robertson, David B. Sanders, Claudia Scarlata, Marko Shuntov, Greta Toni, Maximilian von Wietersheim-Kramsta, John R. Weaver

^*Corresponding author for this work

Research output: Contribution to journal › Article › peer-review

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Abstract

Ordinary matter—including particles such as protons and neutrons—accounts for only about one-sixth of all matter in the Universe. The rest is dark matter, which does not emit or absorb light but plays a fundamental role in galaxy and structure evolution. Because it interacts only through gravity, one of the most direct probes is weak gravitational lensing: the deflection of light from distant galaxies by intervening mass. Here we present an extremely detailed, wide-area weak-lensing mass map covering 0.77° × 0.70°, using high-resolution imaging from the James Webb Space Telescope as part of the COSMOS-Web survey. By measuring the shapes of 129 galaxies per square arcminute—many independently in the F115W and F150W bands—we achieve an angular resolution of 1.00±0.01′. Our map has more than twice the resolution of earlier Hubble Space Telescope maps, revealing how dark and luminous matter co-evolve across filaments, clusters and underdensities. It traces mass features out to z ≈ 2, including the most distant structure at z ≈ 1.1. The sensitivity to high-redshift lensing constrains galaxy environments at the peak of cosmic star formation and sets a high-resolution benchmark for testing theories about the nature of dark matter and the formation of large-scale cosmic structure.

Original language	English
Number of pages	22
Journal	Nature Astronomy
Early online date	26 Jan 2026
DOIs	https://doi.org/10.1038/s41550-025-02763-9
Publication status	Early online - 26 Jan 2026

Keywords

UKRI
STFC
ST/X001075/1
ST/W002612/1
ST/X001997/1
ST/Y509346/1

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An ultra-high-resolution mapAccepted author manuscript (Post-print), 3.73 MBLicence: CC BY

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Scognamiglio, D., Leroy, G., Harvey, D., Massey, R., Rhodes, J., Akins, H. B., Brinch, M., Berman, E., Casey, C. M., Drakos, N. E., Faisst, A. L., Franco, M., Fung, L. W. H., Gozaliasl, G., He, Q., Hatamnia, H., Huff, E., Hogg, N. B., Ilbert, O., ... Weaver, J. R. (2026). An ultra-high-resolution map of (dark) matter. Nature Astronomy. Advance online publication. https://doi.org/10.1038/s41550-025-02763-9

@article{98bdee60a5d74ff09d3fab422dacbdee,

title = "An ultra-high-resolution map of (dark) matter",

abstract = "Ordinary matter—including particles such as protons and neutrons—accounts for only about one-sixth of all matter in the Universe. The rest is dark matter, which does not emit or absorb light but plays a fundamental role in galaxy and structure evolution. Because it interacts only through gravity, one of the most direct probes is weak gravitational lensing: the deflection of light from distant galaxies by intervening mass. Here we present an extremely detailed, wide-area weak-lensing mass map covering 0.77° × 0.70°, using high-resolution imaging from the James Webb Space Telescope as part of the COSMOS-Web survey. By measuring the shapes of 129 galaxies per square arcminute—many independently in the F115W and F150W bands—we achieve an angular resolution of 1.00±0.01′. Our map has more than twice the resolution of earlier Hubble Space Telescope maps, revealing how dark and luminous matter co-evolve across filaments, clusters and underdensities. It traces mass features out to z ≈ 2, including the most distant structure at z ≈ 1.1. The sensitivity to high-redshift lensing constrains galaxy environments at the peak of cosmic star formation and sets a high-resolution benchmark for testing theories about the nature of dark matter and the formation of large-scale cosmic structure.",

keywords = "UKRI, STFC, ST/X001075/1, ST/W002612/1, ST/X001997/1, ST/Y509346/1",

author = "Diana Scognamiglio and Gavin Leroy and David Harvey and Richard Massey and Jason Rhodes and Akins, \{Hollis B.\} and Malte Brinch and Edward Berman and Casey, \{Caitlin M.\} and Drakos, \{Nicole E.\} and Faisst, \{Andreas L.\} and Maximilien Franco and Fung, \{Leo W.H.\} and Ghassem Gozaliasl and Qiuhan He and Hossein Hatamnia and Eric Huff and Hogg, \{Natalie B.\} and Olivier Ilbert and Kartaltepe, \{Jeyhan S.\} and Koekemoer, \{Anton M.\} and Shouwen Jin and Erini Lambrides and Alexie Leauthaud and Lentz, \{Zane D.\} and Daizhong Liu and Guillaume Mahler and Claudia Maraston and Martin, \{Crystal L.\} and Jacqueline McCleary and James Nightingale and Bahram Mobasher and Louise Paquereau and Sandrine Pires and Robertson, \{Brant E.\} and Sanders, \{David B.\} and Claudia Scarlata and Marko Shuntov and Greta Toni and \{von Wietersheim-Kramsta\}, Maximilian and Weaver, \{John R.\}",

note = "Publisher Copyright: {\textcopyright} The Author(s), under exclusive licence to Springer Nature Limited 2026.",

year = "2026",

month = jan,

day = "26",

doi = "10.1038/s41550-025-02763-9",

language = "English",

journal = "Nature Astronomy",

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Scognamiglio, D, Leroy, G, Harvey, D, Massey, R, Rhodes, J, Akins, HB, Brinch, M, Berman, E, Casey, CM, Drakos, NE, Faisst, AL, Franco, M, Fung, LWH, Gozaliasl, G, He, Q, Hatamnia, H, Huff, E, Hogg, NB, Ilbert, O, Kartaltepe, JS, Koekemoer, AM, Jin, S, Lambrides, E, Leauthaud, A, Lentz, ZD, Liu, D, Mahler, G, Maraston, C, Martin, CL, McCleary, J, Nightingale, J, Mobasher, B, Paquereau, L, Pires, S, Robertson, BE, Sanders, DB, Scarlata, C, Shuntov, M, Toni, G, von Wietersheim-Kramsta, M & Weaver, JR 2026, 'An ultra-high-resolution map of (dark) matter', Nature Astronomy. https://doi.org/10.1038/s41550-025-02763-9

TY - JOUR

T1 - An ultra-high-resolution map of (dark) matter

AU - Scognamiglio, Diana

AU - Leroy, Gavin

AU - Harvey, David

AU - Massey, Richard

AU - Rhodes, Jason

AU - Akins, Hollis B.

AU - Brinch, Malte

AU - Berman, Edward

AU - Casey, Caitlin M.

AU - Drakos, Nicole E.

AU - Faisst, Andreas L.

AU - Franco, Maximilien

AU - Fung, Leo W.H.

AU - Gozaliasl, Ghassem

AU - He, Qiuhan

AU - Hatamnia, Hossein

AU - Huff, Eric

AU - Hogg, Natalie B.

AU - Ilbert, Olivier

AU - Kartaltepe, Jeyhan S.

AU - Koekemoer, Anton M.

AU - Jin, Shouwen

AU - Lambrides, Erini

AU - Leauthaud, Alexie

AU - Lentz, Zane D.

AU - Liu, Daizhong

AU - Mahler, Guillaume

AU - Maraston, Claudia

AU - Martin, Crystal L.

AU - McCleary, Jacqueline

AU - Nightingale, James

AU - Mobasher, Bahram

AU - Paquereau, Louise

AU - Pires, Sandrine

AU - Robertson, Brant E.

AU - Sanders, David B.

AU - Scarlata, Claudia

AU - Shuntov, Marko

AU - Toni, Greta

AU - von Wietersheim-Kramsta, Maximilian

AU - Weaver, John R.

PY - 2026/1/26

Y1 - 2026/1/26

N2 - Ordinary matter—including particles such as protons and neutrons—accounts for only about one-sixth of all matter in the Universe. The rest is dark matter, which does not emit or absorb light but plays a fundamental role in galaxy and structure evolution. Because it interacts only through gravity, one of the most direct probes is weak gravitational lensing: the deflection of light from distant galaxies by intervening mass. Here we present an extremely detailed, wide-area weak-lensing mass map covering 0.77° × 0.70°, using high-resolution imaging from the James Webb Space Telescope as part of the COSMOS-Web survey. By measuring the shapes of 129 galaxies per square arcminute—many independently in the F115W and F150W bands—we achieve an angular resolution of 1.00±0.01′. Our map has more than twice the resolution of earlier Hubble Space Telescope maps, revealing how dark and luminous matter co-evolve across filaments, clusters and underdensities. It traces mass features out to z ≈ 2, including the most distant structure at z ≈ 1.1. The sensitivity to high-redshift lensing constrains galaxy environments at the peak of cosmic star formation and sets a high-resolution benchmark for testing theories about the nature of dark matter and the formation of large-scale cosmic structure.

AB - Ordinary matter—including particles such as protons and neutrons—accounts for only about one-sixth of all matter in the Universe. The rest is dark matter, which does not emit or absorb light but plays a fundamental role in galaxy and structure evolution. Because it interacts only through gravity, one of the most direct probes is weak gravitational lensing: the deflection of light from distant galaxies by intervening mass. Here we present an extremely detailed, wide-area weak-lensing mass map covering 0.77° × 0.70°, using high-resolution imaging from the James Webb Space Telescope as part of the COSMOS-Web survey. By measuring the shapes of 129 galaxies per square arcminute—many independently in the F115W and F150W bands—we achieve an angular resolution of 1.00±0.01′. Our map has more than twice the resolution of earlier Hubble Space Telescope maps, revealing how dark and luminous matter co-evolve across filaments, clusters and underdensities. It traces mass features out to z ≈ 2, including the most distant structure at z ≈ 1.1. The sensitivity to high-redshift lensing constrains galaxy environments at the peak of cosmic star formation and sets a high-resolution benchmark for testing theories about the nature of dark matter and the formation of large-scale cosmic structure.

KW - UKRI

KW - STFC

KW - ST/X001075/1

KW - ST/W002612/1

KW - ST/X001997/1

KW - ST/Y509346/1

UR - https://www.scopus.com/pages/publications/105028415017

U2 - 10.1038/s41550-025-02763-9

DO - 10.1038/s41550-025-02763-9

M3 - Article

AN - SCOPUS:105028415017

SN - 2397-3366

JO - Nature Astronomy

JF - Nature Astronomy

ER -

An ultra-high-resolution map of (dark) matter

Abstract

Keywords

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