COMAP Early Science: VIII. A Joint Stacking Analysis with eBOSS Quasars

Delaney A. Dunne; Kieran A. Cleary; Patrick C. Breysse; Dongwoo T. Chung; Havard T. Ihle; J. Richard Bond; Hans Kristian Eriksen; Joshua Ott Gundersen; Laura C. Keating; Junhan Kim; Jonas Gahr Sturtzel Lunde; Norman Murray; Hamsa Padmanabhan; Liju Philip; Nils-Ole Stutzer; Doga Tolgay; Ingunn Katherine Wehus; Sarah E. Church; Todd Gaier; Andrew I. Harris; Richard Hobbs; James W. Lamb; Charles R. Lawrence; Anthony C. S. Readhead; David P. Woody

doi:10.3847/1538-4357/ad2dfc

COMAP Early Science: VIII. A Joint Stacking Analysis with eBOSS Quasars

Delaney A. Dunne, Kieran A. Cleary, Patrick C. Breysse, Dongwoo T. Chung, Havard T. Ihle, J. Richard Bond, Hans Kristian Eriksen, Joshua Ott Gundersen, Laura C. Keating, Junhan Kim, Jonas Gahr Sturtzel Lunde, Norman Murray, Hamsa Padmanabhan, Liju Philip, Nils-Ole Stutzer, Doga Tolgay, Ingunn Katherine Wehus, Sarah E. Church, Todd Gaier, Andrew I. HarrisRichard Hobbs, James W. Lamb, Charles R. Lawrence, Anthony C. S. Readhead, David P. Woody

School of Physics and Astronomy

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

Abstract

We present a new upper limit on the cosmic molecular gas density at z = 2.4 − 3.4 obtained using the first year of observations from the CO Mapping Array Project (COMAP). COMAP data cubes are stacked on the 3D positions of 243 quasars selected from the Extended Baryon Oscillation Spectroscopic
Survey (eBOSS) catalog, yielding a 95% upper limit for flux from CO(1-0) line emission of 0.129 Jykm/s. Depending on the balance of the emission between the quasar host and its environment, this value can be interpreted as an average CO line luminosity L′CO of eBOSS quasars of ≤ 1.26 × 1011 K km pc2s−1, or an average molecular gas density ρH2 in regions of the universe containing a quasar of ≤ 1.52 × 108 M⊙ cMpc−3. The L′ CO upper limit falls among CO line luminosities obtained fromindividually-targeted quasars in the COMAP redshift range, and the ρH2 value is comparable to upper limits obtained from other Line Intensity Mapping (LIM) surveys and their joint analyses. Further, we forecast the values obtainable with the COMAP/eBOSS stack after the full 5-year COMAP Pathfinder survey. We predict that a detection is probable with this method, depending on the CO properties of the quasar sample. Based on the achieved sensitivity, we believe that this technique of stacking LIM data on the positions of traditional galaxy or quasar catalogs is extremely promising, both as
a technique for investigating large galaxy catalogs efficiently at high redshift and as a technique for bolstering the sensitivity of LIM experiments, even with a fraction of their total expected survey data.

Original language	English
Article number	7
Pages (from-to)	1-21
Number of pages	21
Journal	Astrophysical Journal
Volume	965
Issue number	1
DOIs	https://doi.org/10.3847/1538-4357/ad2dfc
Publication status	Published - 1 Apr 2024

Keywords / Materials (for Non-textual outputs)

CO line emission (262)
Cosmological evolution (336)
High-redshift galaxies (734)
Molecular gas (1073)
Quasars (1319)
Radio astronomy (1338)

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Dunne, D. A., Cleary, K. A., Breysse, P. C., Chung, D. T., Ihle, H. T., Bond, J. R., Eriksen, H. K., Gundersen, J. O., Keating, L. C., Kim, J., Lunde, J. G. S., Murray, N., Padmanabhan, H., Philip, L., Stutzer, N.-O., Tolgay, D., Wehus, I. K., Church, S. E., Gaier, T., ... Woody, D. P. (2024). COMAP Early Science: VIII. A Joint Stacking Analysis with eBOSS Quasars. Astrophysical Journal, 965(1), 1-21. Article 7. https://doi.org/10.3847/1538-4357/ad2dfc

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title = "COMAP Early Science: VIII. A Joint Stacking Analysis with eBOSS Quasars",

abstract = "We present a new upper limit on the cosmic molecular gas density at z = 2.4 − 3.4 obtained using the first year of observations from the CO Mapping Array Project (COMAP). COMAP data cubes are stacked on the 3D positions of 243 quasars selected from the Extended Baryon Oscillation SpectroscopicSurvey (eBOSS) catalog, yielding a 95% upper limit for flux from CO(1-0) line emission of 0.129 Jykm/s. Depending on the balance of the emission between the quasar host and its environment, this value can be interpreted as an average CO line luminosity L′CO of eBOSS quasars of ≤ 1.26 × 1011 K km pc2s−1, or an average molecular gas density ρH2 in regions of the universe containing a quasar of ≤ 1.52 × 108 M⊙ cMpc−3. The L′ CO upper limit falls among CO line luminosities obtained fromindividually-targeted quasars in the COMAP redshift range, and the ρH2 value is comparable to upper limits obtained from other Line Intensity Mapping (LIM) surveys and their joint analyses. Further, we forecast the values obtainable with the COMAP/eBOSS stack after the full 5-year COMAP Pathfinder survey. We predict that a detection is probable with this method, depending on the CO properties of the quasar sample. Based on the achieved sensitivity, we believe that this technique of stacking LIM data on the positions of traditional galaxy or quasar catalogs is extremely promising, both asa technique for investigating large galaxy catalogs efficiently at high redshift and as a technique for bolstering the sensitivity of LIM experiments, even with a fraction of their total expected survey data.",

keywords = "CO line emission (262), Cosmological evolution (336), High-redshift galaxies (734), Molecular gas (1073), Quasars (1319), Radio astronomy (1338)",

author = "Dunne, {Delaney A.} and Cleary, {Kieran A.} and Breysse, {Patrick C.} and Chung, {Dongwoo T.} and Ihle, {Havard T.} and Bond, {J. Richard} and Eriksen, {Hans Kristian} and Gundersen, {Joshua Ott} and Keating, {Laura C.} and Junhan Kim and Lunde, {Jonas Gahr Sturtzel} and Norman Murray and Hamsa Padmanabhan and Liju Philip and Nils-Ole Stutzer and Doga Tolgay and Wehus, {Ingunn Katherine} and Church, {Sarah E.} and Todd Gaier and Harris, {Andrew I.} and Richard Hobbs and Lamb, {James W.} and Lawrence, {Charles R.} and Readhead, {Anthony C. S.} and Woody, {David P.}",

note = "26 pages, 22 figures; Version 2 is as accepted by ApJ",

year = "2024",

month = apr,

day = "1",

doi = "10.3847/1538-4357/ad2dfc",

language = "English",

volume = "965",

pages = "1--21",

journal = "Astrophysical Journal",

issn = "0004-637X",

publisher = "IOP Publishing",

number = "1",

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Dunne, DA, Cleary, KA, Breysse, PC, Chung, DT, Ihle, HT, Bond, JR, Eriksen, HK, Gundersen, JO, Keating, LC, Kim, J, Lunde, JGS, Murray, N, Padmanabhan, H, Philip, L, Stutzer, N-O, Tolgay, D, Wehus, IK, Church, SE, Gaier, T, Harris, AI, Hobbs, R, Lamb, JW, Lawrence, CR, Readhead, ACS & Woody, DP 2024, 'COMAP Early Science: VIII. A Joint Stacking Analysis with eBOSS Quasars', Astrophysical Journal, vol. 965, no. 1, 7, pp. 1-21. https://doi.org/10.3847/1538-4357/ad2dfc

TY - JOUR

T1 - COMAP Early Science: VIII. A Joint Stacking Analysis with eBOSS Quasars

AU - Dunne, Delaney A.

AU - Cleary, Kieran A.

AU - Breysse, Patrick C.

AU - Chung, Dongwoo T.

AU - Ihle, Havard T.

AU - Bond, J. Richard

AU - Eriksen, Hans Kristian

AU - Gundersen, Joshua Ott

AU - Keating, Laura C.

AU - Kim, Junhan

AU - Lunde, Jonas Gahr Sturtzel

AU - Murray, Norman

AU - Padmanabhan, Hamsa

AU - Philip, Liju

AU - Stutzer, Nils-Ole

AU - Tolgay, Doga

AU - Wehus, Ingunn Katherine

AU - Church, Sarah E.

AU - Gaier, Todd

AU - Harris, Andrew I.

AU - Hobbs, Richard

AU - Lamb, James W.

AU - Lawrence, Charles R.

AU - Readhead, Anthony C. S.

AU - Woody, David P.

N1 - 26 pages, 22 figures; Version 2 is as accepted by ApJ

PY - 2024/4/1

Y1 - 2024/4/1

N2 - We present a new upper limit on the cosmic molecular gas density at z = 2.4 − 3.4 obtained using the first year of observations from the CO Mapping Array Project (COMAP). COMAP data cubes are stacked on the 3D positions of 243 quasars selected from the Extended Baryon Oscillation SpectroscopicSurvey (eBOSS) catalog, yielding a 95% upper limit for flux from CO(1-0) line emission of 0.129 Jykm/s. Depending on the balance of the emission between the quasar host and its environment, this value can be interpreted as an average CO line luminosity L′CO of eBOSS quasars of ≤ 1.26 × 1011 K km pc2s−1, or an average molecular gas density ρH2 in regions of the universe containing a quasar of ≤ 1.52 × 108 M⊙ cMpc−3. The L′ CO upper limit falls among CO line luminosities obtained fromindividually-targeted quasars in the COMAP redshift range, and the ρH2 value is comparable to upper limits obtained from other Line Intensity Mapping (LIM) surveys and their joint analyses. Further, we forecast the values obtainable with the COMAP/eBOSS stack after the full 5-year COMAP Pathfinder survey. We predict that a detection is probable with this method, depending on the CO properties of the quasar sample. Based on the achieved sensitivity, we believe that this technique of stacking LIM data on the positions of traditional galaxy or quasar catalogs is extremely promising, both asa technique for investigating large galaxy catalogs efficiently at high redshift and as a technique for bolstering the sensitivity of LIM experiments, even with a fraction of their total expected survey data.

AB - We present a new upper limit on the cosmic molecular gas density at z = 2.4 − 3.4 obtained using the first year of observations from the CO Mapping Array Project (COMAP). COMAP data cubes are stacked on the 3D positions of 243 quasars selected from the Extended Baryon Oscillation SpectroscopicSurvey (eBOSS) catalog, yielding a 95% upper limit for flux from CO(1-0) line emission of 0.129 Jykm/s. Depending on the balance of the emission between the quasar host and its environment, this value can be interpreted as an average CO line luminosity L′CO of eBOSS quasars of ≤ 1.26 × 1011 K km pc2s−1, or an average molecular gas density ρH2 in regions of the universe containing a quasar of ≤ 1.52 × 108 M⊙ cMpc−3. The L′ CO upper limit falls among CO line luminosities obtained fromindividually-targeted quasars in the COMAP redshift range, and the ρH2 value is comparable to upper limits obtained from other Line Intensity Mapping (LIM) surveys and their joint analyses. Further, we forecast the values obtainable with the COMAP/eBOSS stack after the full 5-year COMAP Pathfinder survey. We predict that a detection is probable with this method, depending on the CO properties of the quasar sample. Based on the achieved sensitivity, we believe that this technique of stacking LIM data on the positions of traditional galaxy or quasar catalogs is extremely promising, both asa technique for investigating large galaxy catalogs efficiently at high redshift and as a technique for bolstering the sensitivity of LIM experiments, even with a fraction of their total expected survey data.

KW - CO line emission (262)

KW - Cosmological evolution (336)

KW - High-redshift galaxies (734)

KW - Molecular gas (1073)

KW - Quasars (1319)

KW - Radio astronomy (1338)

U2 - 10.3847/1538-4357/ad2dfc

DO - 10.3847/1538-4357/ad2dfc

M3 - Article

SN - 0004-637X

VL - 965

SP - 1

EP - 21

JO - Astrophysical Journal

JF - Astrophysical Journal

IS - 1

M1 - 7

ER -

COMAP Early Science: VIII. A Joint Stacking Analysis with eBOSS Quasars

Abstract

Keywords / Materials (for Non-textual outputs)

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