WEAVE First Light Observations: Origin and Dynamics of the Shock Front in Stephan’s Quintet

M. I. Arnaudova; S. Das; D. J.B. Smith; M. J. Hardcastle; N. Hatch; S. C. Trager; R. J. Smith; A. B. Drake; J. C. McGarry; S. Shenoy; J. P. Stott; J. H. Knapen; K. M. Hess; K. J. Duncan; A. Gloudemans; P. N. Best; R. García-Benito; R. Kondapally; M. Balcells; G. S. Couto; D. C. Abrams; D. Aguado; J. A.L. Aguerri; R. Barrena; C. R. Benn; T. Bensby; S. R. Berlanas; D. Bettoni; D. Cano-Infantes; R. Carrera; P. J. Concepción; G. B. Dalton; G. D’Ago; K. Dee; L. Domínguez-Palmero; J. E. Drew; E. L. Escott; C. Fariña; M. Fossati; M. Fumagalli; E. Gafton; F. J. Gribbin; S. Hughes; A. Iovino; S. Jin; I. J. Lewis; M. Longhetti; J. Méndez-Abreu; A. Mercurio; A. Molaeinezhad; E. Molinari; M. Monguió; D. N.A. Murphy; S. Picó; M. M. Pieri; A. W. Ridings; M. Romero-Gómez; E. Schallig; T. W. Shimwell; J. Skvarč; R. Stuik; A. Vallenari; J. M. van der Hulst; N. A. Walton; C. C. Worley

doi:10.1093/mnras/stae2235

WEAVE First Light Observations: Origin and Dynamics of the Shock Front in Stephan’s Quintet

M. I. Arnaudova^*, S. Das^*, D. J.B. Smith, M. J. Hardcastle, N. Hatch, S. C. Trager, R. J. Smith, A. B. Drake, J. C. McGarry, S. Shenoy, J. P. Stott, J. H. Knapen, K. M. Hess, K. J. Duncan, A. Gloudemans, P. N. Best, R. García-Benito, R. Kondapally, M. Balcells, G. S. CoutoD. C. Abrams, D. Aguado, J. A.L. Aguerri, R. Barrena, C. R. Benn, T. Bensby, S. R. Berlanas, D. Bettoni, D. Cano-Infantes, R. Carrera, P. J. Concepción, G. B. Dalton, G. D’Ago, K. Dee, L. Domínguez-Palmero, J. E. Drew, E. L. Escott, C. Fariña, M. Fossati, M. Fumagalli, E. Gafton, F. J. Gribbin, S. Hughes, A. Iovino, S. Jin, I. J. Lewis, M. Longhetti, J. Méndez-Abreu, A. Mercurio, A. Molaeinezhad, E. Molinari, M. Monguió, D. N.A. Murphy, S. Picó, M. M. Pieri, A. W. Ridings, M. Romero-Gómez, E. Schallig, T. W. Shimwell, J. Skvarč, R. Stuik, A. Vallenari, J. M. van der Hulst, N. A. Walton, C. C. Worley

^*Corresponding author for this work

School of Physics and Astronomy

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

Abstract

We present a detailed study of the large-scale shock front in Stephan’s Quintet, a by-product of past and ongoing interactions. Using integral-field spectroscopy from the new William Herschel Telescope Enhanced Area Velocity Explorer (WEAVE), recent 144 MHz observations from the LOFAR Two-metre Sky Survey, and archival data from the Very Large Array and JWST, we obtain new measurements of key shock properties and determine its impact on the system. Harnessing the WEAVE large integral field unit’s field of view (90 × 78 arcsec²), spectral resolution (R ∼ 2500), and continuous wavelength coverage across the optical band, we perform robust emission-line modelling and dynamically locate the shock within the multiphase intergalactic medium with higher precision than previously possible. The shocking of the cold gas phase is hypersonic, and comparisons with shock models show that it can readily account for the observed emission-line ratios. In contrast, we demonstrate that the shock is relatively weak in the hot plasma visible in X-rays (with Mach number of M ∼ 2–4), making it inefficient at producing the relativistic particles needed to explain the observed synchrotron emission. Instead, we propose that it has led to an adiabatic compression of the medium, which has increased the radio luminosity 10-fold. Comparison of the Balmer line-derived extinction map with the molecular gas and hot dust observed with JWST suggests that pre-existing dust may have survived the collision, allowing the condensation of H₂ – a key channel for dissipating the shock energy.

Original language	English
Pages (from-to)	2269-2290
Number of pages	22
Journal	Monthly Notices of the Royal Astronomical Society
Volume	535
Issue number	3
Early online date	22 Nov 2024
DOIs	https://doi.org/10.1093/mnras/stae2235
Publication status	Published - 1 Dec 2024

Keywords / Materials (for Non-textual outputs)

galaxies: groups: individual: Stephan’s Quintet
galaxies: interactions
radio continuum: ISM
techniques: imaging spectroscopy

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10.1093/mnras/stae2235Licence: Creative Commons: Attribution (CC-BY)

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Arnaudova, M. I., Das, S., Smith, D. J. B., Hardcastle, M. J., Hatch, N., Trager, S. C., Smith, R. J., Drake, A. B., McGarry, J. C., Shenoy, S., Stott, J. P., Knapen, J. H., Hess, K. M., Duncan, K. J., Gloudemans, A., Best, P. N., García-Benito, R., Kondapally, R., Balcells, M., ... Worley, C. C. (2024). WEAVE First Light Observations: Origin and Dynamics of the Shock Front in Stephan’s Quintet. Monthly Notices of the Royal Astronomical Society, 535(3), 2269-2290. https://doi.org/10.1093/mnras/stae2235

@article{3f625b67f6294618aab89d6e9249b810,

title = "WEAVE First Light Observations: Origin and Dynamics of the Shock Front in Stephan{\textquoteright}s Quintet",

abstract = "We present a detailed study of the large-scale shock front in Stephan{\textquoteright}s Quintet, a by-product of past and ongoing interactions. Using integral-field spectroscopy from the new William Herschel Telescope Enhanced Area Velocity Explorer (WEAVE), recent 144 MHz observations from the LOFAR Two-metre Sky Survey, and archival data from the Very Large Array and JWST, we obtain new measurements of key shock properties and determine its impact on the system. Harnessing the WEAVE large integral field unit{\textquoteright}s field of view (90 × 78 arcsec2), spectral resolution (R ∼ 2500), and continuous wavelength coverage across the optical band, we perform robust emission-line modelling and dynamically locate the shock within the multiphase intergalactic medium with higher precision than previously possible. The shocking of the cold gas phase is hypersonic, and comparisons with shock models show that it can readily account for the observed emission-line ratios. In contrast, we demonstrate that the shock is relatively weak in the hot plasma visible in X-rays (with Mach number of M ∼ 2–4), making it inefficient at producing the relativistic particles needed to explain the observed synchrotron emission. Instead, we propose that it has led to an adiabatic compression of the medium, which has increased the radio luminosity 10-fold. Comparison of the Balmer line-derived extinction map with the molecular gas and hot dust observed with JWST suggests that pre-existing dust may have survived the collision, allowing the condensation of H2 – a key channel for dissipating the shock energy.",

keywords = "galaxies: groups: individual: Stephan{\textquoteright}s Quintet, galaxies: interactions, radio continuum: ISM, techniques: imaging spectroscopy",

author = "Arnaudova, {M. I.} and S. Das and Smith, {D. J.B.} and Hardcastle, {M. J.} and N. Hatch and Trager, {S. C.} and Smith, {R. J.} and Drake, {A. B.} and McGarry, {J. C.} and S. Shenoy and Stott, {J. P.} and Knapen, {J. H.} and Hess, {K. M.} and Duncan, {K. J.} and A. Gloudemans and Best, {P. N.} and R. Garc{\'i}a-Benito and R. Kondapally and M. Balcells and Couto, {G. S.} and Abrams, {D. C.} and D. Aguado and Aguerri, {J. A.L.} and R. Barrena and Benn, {C. R.} and T. Bensby and Berlanas, {S. R.} and D. Bettoni and D. Cano-Infantes and R. Carrera and Concepci{\'o}n, {P. J.} and Dalton, {G. B.} and G. D{\textquoteright}Ago and K. Dee and L. Dom{\'i}nguez-Palmero and Drew, {J. E.} and Escott, {E. L.} and C. Fari{\~n}a and M. Fossati and M. Fumagalli and E. Gafton and Gribbin, {F. J.} and S. Hughes and A. Iovino and S. Jin and Lewis, {I. J.} and M. Longhetti and J. M{\'e}ndez-Abreu and A. Mercurio and A. Molaeinezhad and E. Molinari and M. Mongui{\'o} and Murphy, {D. N.A.} and S. Pic{\'o} and Pieri, {M. M.} and Ridings, {A. W.} and M. Romero-G{\'o}mez and E. Schallig and Shimwell, {T. W.} and J. Skvar{\v c} and R. Stuik and A. Vallenari and {van der Hulst}, {J. M.} and Walton, {N. A.} and Worley, {C. C.}",

note = "Publisher Copyright: {\textcopyright} 2024 The Author(s).",

year = "2024",

month = dec,

day = "1",

doi = "10.1093/mnras/stae2235",

language = "English",

volume = "535",

pages = "2269--2290",

journal = "Monthly Notices of the Royal Astronomical Society",

issn = "0035-8711",

publisher = "Oxford University Press",

number = "3",

}

Arnaudova, MI, Das, S, Smith, DJB, Hardcastle, MJ, Hatch, N, Trager, SC, Smith, RJ, Drake, AB, McGarry, JC, Shenoy, S, Stott, JP, Knapen, JH, Hess, KM, Duncan, KJ, Gloudemans, A, Best, PN, García-Benito, R, Kondapally, R, Balcells, M, Couto, GS, Abrams, DC, Aguado, D, Aguerri, JAL, Barrena, R, Benn, CR, Bensby, T, Berlanas, SR, Bettoni, D, Cano-Infantes, D, Carrera, R, Concepción, PJ, Dalton, GB, D’Ago, G, Dee, K, Domínguez-Palmero, L, Drew, JE, Escott, EL, Fariña, C, Fossati, M, Fumagalli, M, Gafton, E, Gribbin, FJ, Hughes, S, Iovino, A, Jin, S, Lewis, IJ, Longhetti, M, Méndez-Abreu, J, Mercurio, A, Molaeinezhad, A, Molinari, E, Monguió, M, Murphy, DNA, Picó, S, Pieri, MM, Ridings, AW, Romero-Gómez, M, Schallig, E, Shimwell, TW, Skvarč, J, Stuik, R, Vallenari, A, van der Hulst, JM, Walton, NA & Worley, CC 2024, 'WEAVE First Light Observations: Origin and Dynamics of the Shock Front in Stephan’s Quintet', Monthly Notices of the Royal Astronomical Society, vol. 535, no. 3, pp. 2269-2290. https://doi.org/10.1093/mnras/stae2235

TY - JOUR

T1 - WEAVE First Light Observations: Origin and Dynamics of the Shock Front in Stephan’s Quintet

AU - Arnaudova, M. I.

AU - Das, S.

AU - Smith, D. J.B.

AU - Hardcastle, M. J.

AU - Hatch, N.

AU - Trager, S. C.

AU - Smith, R. J.

AU - Drake, A. B.

AU - McGarry, J. C.

AU - Shenoy, S.

AU - Stott, J. P.

AU - Knapen, J. H.

AU - Hess, K. M.

AU - Duncan, K. J.

AU - Gloudemans, A.

AU - Best, P. N.

AU - García-Benito, R.

AU - Kondapally, R.

AU - Balcells, M.

AU - Couto, G. S.

AU - Abrams, D. C.

AU - Aguado, D.

AU - Aguerri, J. A.L.

AU - Barrena, R.

AU - Benn, C. R.

AU - Bensby, T.

AU - Berlanas, S. R.

AU - Bettoni, D.

AU - Cano-Infantes, D.

AU - Carrera, R.

AU - Concepción, P. J.

AU - Dalton, G. B.

AU - D’Ago, G.

AU - Dee, K.

AU - Domínguez-Palmero, L.

AU - Drew, J. E.

AU - Escott, E. L.

AU - Fariña, C.

AU - Fossati, M.

AU - Fumagalli, M.

AU - Gafton, E.

AU - Gribbin, F. J.

AU - Hughes, S.

AU - Iovino, A.

AU - Jin, S.

AU - Lewis, I. J.

AU - Longhetti, M.

AU - Méndez-Abreu, J.

AU - Mercurio, A.

AU - Molaeinezhad, A.

AU - Molinari, E.

AU - Monguió, M.

AU - Murphy, D. N.A.

AU - Picó, S.

AU - Pieri, M. M.

AU - Ridings, A. W.

AU - Romero-Gómez, M.

AU - Schallig, E.

AU - Shimwell, T. W.

AU - Skvarč, J.

AU - Stuik, R.

AU - Vallenari, A.

AU - van der Hulst, J. M.

AU - Walton, N. A.

AU - Worley, C. C.

PY - 2024/12/1

Y1 - 2024/12/1

N2 - We present a detailed study of the large-scale shock front in Stephan’s Quintet, a by-product of past and ongoing interactions. Using integral-field spectroscopy from the new William Herschel Telescope Enhanced Area Velocity Explorer (WEAVE), recent 144 MHz observations from the LOFAR Two-metre Sky Survey, and archival data from the Very Large Array and JWST, we obtain new measurements of key shock properties and determine its impact on the system. Harnessing the WEAVE large integral field unit’s field of view (90 × 78 arcsec2), spectral resolution (R ∼ 2500), and continuous wavelength coverage across the optical band, we perform robust emission-line modelling and dynamically locate the shock within the multiphase intergalactic medium with higher precision than previously possible. The shocking of the cold gas phase is hypersonic, and comparisons with shock models show that it can readily account for the observed emission-line ratios. In contrast, we demonstrate that the shock is relatively weak in the hot plasma visible in X-rays (with Mach number of M ∼ 2–4), making it inefficient at producing the relativistic particles needed to explain the observed synchrotron emission. Instead, we propose that it has led to an adiabatic compression of the medium, which has increased the radio luminosity 10-fold. Comparison of the Balmer line-derived extinction map with the molecular gas and hot dust observed with JWST suggests that pre-existing dust may have survived the collision, allowing the condensation of H2 – a key channel for dissipating the shock energy.

AB - We present a detailed study of the large-scale shock front in Stephan’s Quintet, a by-product of past and ongoing interactions. Using integral-field spectroscopy from the new William Herschel Telescope Enhanced Area Velocity Explorer (WEAVE), recent 144 MHz observations from the LOFAR Two-metre Sky Survey, and archival data from the Very Large Array and JWST, we obtain new measurements of key shock properties and determine its impact on the system. Harnessing the WEAVE large integral field unit’s field of view (90 × 78 arcsec2), spectral resolution (R ∼ 2500), and continuous wavelength coverage across the optical band, we perform robust emission-line modelling and dynamically locate the shock within the multiphase intergalactic medium with higher precision than previously possible. The shocking of the cold gas phase is hypersonic, and comparisons with shock models show that it can readily account for the observed emission-line ratios. In contrast, we demonstrate that the shock is relatively weak in the hot plasma visible in X-rays (with Mach number of M ∼ 2–4), making it inefficient at producing the relativistic particles needed to explain the observed synchrotron emission. Instead, we propose that it has led to an adiabatic compression of the medium, which has increased the radio luminosity 10-fold. Comparison of the Balmer line-derived extinction map with the molecular gas and hot dust observed with JWST suggests that pre-existing dust may have survived the collision, allowing the condensation of H2 – a key channel for dissipating the shock energy.

KW - galaxies: groups: individual: Stephan’s Quintet

KW - galaxies: interactions

KW - radio continuum: ISM

KW - techniques: imaging spectroscopy

UR - http://www.scopus.com/inward/record.url?scp=85210391459&partnerID=8YFLogxK

U2 - 10.1093/mnras/stae2235

DO - 10.1093/mnras/stae2235

M3 - Article

AN - SCOPUS:85210391459

SN - 0035-8711

VL - 535

SP - 2269

EP - 2290

JO - Monthly Notices of the Royal Astronomical Society

JF - Monthly Notices of the Royal Astronomical Society

IS - 3

ER -

WEAVE First Light Observations: Origin and Dynamics of the Shock Front in Stephan’s Quintet

Abstract

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Revealing the hidden early lives of super-massive black holes

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WEAVE First Light Observations: Origin and Dynamics of the Shock Front in Stephan’s Quintet

Abstract

Keywords / Materials (for Non-textual outputs)

Access to Document

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Revealing the hidden early lives of super-massive black holes

Astronomy and Astrophysics at Edinburgh

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