A cryogenic silicon interferometer for gravitational-wave detection

R.X. Adhikari; K. Arai; A.F. Brooks; C. Wipf; O. Aguiar; P. Altin; B. Barr; L. Barsotti; R. Bassiri; A. Bell; G. Billingsley; R. Birney; D. Blair; E. Bonilla; J. Briggs; D.D. Brown; R. Byer; H. Cao; M. Constancio; S. Cooper; T. Corbitt; D. Coyne; A. Cumming; E. Daw; R. Derosa; G. Eddolls; J. Eichholz; M. Evans; M. Fejer; E.C. Ferreira; A. Freise; V.V. Frolov; S. Gras; A. Green; H. Grote; E. Gustafson; E.D. Hall; G. Hammond; J. Harms; G. Harry; K. Haughian; D. Heinert; M. Heintze; F. Hellman; J. Hennig; M. Hennig; S. Hild; J. Hough; W. Johnson; B. Kamai; D. Kapasi; K. Komori; D. Koptsov; M. Korobko; W.Z. Korth; K. Kuns; B. Lantz; S. Leavey; F. Magana-Sandoval; G. Mansell; A. Markosyan; A. Markowitz; I. Martin; R. Martin; D. Martynov; D.E. Mcclelland; G. Mcghee; T. Mcrae; J. Mills; V. Mitrofanov; M. Molina-Ruiz; C. Mow-Lowry; J. Munch; P. Murray; S. Ng; M.A. Okada; D.J. Ottaway; L. Prokhorov; V. Quetschke; S. Reid; D. Reitze; J. Richardson; R. Robie; I. Romero-Shaw; R. Route; S. Rowan; R. Schnabel; M. Schneewind; F. Seifert; D. Shaddock; B. Shapiro; D. Shoemaker; A.S. Silva; B. Slagmolen; J. Smith; N. Smith; J. Steinlechner; K. Strain; D. Taira; S. Tait; D. Tanner; Z. Tornasi; C. Torrie; M. Van Veggel; J. Vanheijningen; P. Veitch; A. Wade; G. Wallace; R. Ward; R. Weiss; P. Wessels; B. Willke; H. Yamamoto; M.J. Yap; C. Zhao

doi:10.1088/1361-6382/ab9143

A cryogenic silicon interferometer for gravitational-wave detection

R.X. Adhikari, K. Arai, A.F. Brooks, C. Wipf, O. Aguiar, P. Altin, B. Barr, L. Barsotti, R. Bassiri, A. Bell, G. Billingsley, R. Birney, D. Blair, E. Bonilla, J. Briggs, D.D. Brown, R. Byer, H. Cao, M. Constancio, S. CooperT. Corbitt, D. Coyne, A. Cumming, E. Daw, R. Derosa, G. Eddolls, J. Eichholz, M. Evans, M. Fejer, E.C. Ferreira, A. Freise, V.V. Frolov, S. Gras, A. Green, H. Grote, E. Gustafson, E.D. Hall, G. Hammond, J. Harms, G. Harry, K. Haughian, D. Heinert, M. Heintze, F. Hellman, J. Hennig, M. Hennig, S. Hild, J. Hough, W. Johnson, B. Kamai, D. Kapasi, K. Komori, D. Koptsov, M. Korobko, W.Z. Korth, K. Kuns, B. Lantz, S. Leavey, F. Magana-Sandoval, G. Mansell, A. Markosyan, A. Markowitz, I. Martin, R. Martin, D. Martynov, D.E. Mcclelland, G. Mcghee, T. Mcrae, J. Mills, V. Mitrofanov, M. Molina-Ruiz, C. Mow-Lowry, J. Munch, P. Murray, S. Ng, M.A. Okada, D.J. Ottaway, L. Prokhorov, V. Quetschke, S. Reid, D. Reitze, J. Richardson, R. Robie, I. Romero-Shaw, R. Route, S. Rowan, R. Schnabel, M. Schneewind, F. Seifert, D. Shaddock, B. Shapiro, D. Shoemaker, A.S. Silva, B. Slagmolen, J. Smith, N. Smith, J. Steinlechner, K. Strain, D. Taira, S. Tait, D. Tanner, Z. Tornasi, C. Torrie, M. Van Veggel, J. Vanheijningen, P. Veitch, A. Wade, G. Wallace, R. Ward, R. Weiss, P. Wessels, B. Willke, H. Yamamoto, M.J. Yap, C. Zhao

Research output: Contribution to Journal › Article › Academic › peer-review

Abstract

© 2020 IOP Publishing Ltd.The detection of gravitational waves from compact binary mergers by LIGO has opened the era of gravitational wave astronomy, revealing a previously hidden side of the cosmos. To maximize the reach of the existing LIGO observatory facilities, we have designed a new instrument able to detect gravitational waves at distances 5 times further away than possible with Advanced LIGO, or at greater than 100 times the event rate. Observations with this new instrument will make possible dramatic steps toward understanding the physics of the nearby Universe, as well as observing the Universe out to cosmological distances by the detection of binary black hole coalescences. This article presents the instrument design and a quantitative analysis of the anticipated noise floor.

Original language	English
Article number	165003
Journal	Classical and Quantum Gravity
Volume	37
Issue number	16
DOIs	https://doi.org/10.1088/1361-6382/ab9143
Publication status	Published - 20 Aug 2020
Externally published	Yes

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Adhikari, R. X., Arai, K., Brooks, A. F., Wipf, C., Aguiar, O., Altin, P., Barr, B., Barsotti, L., Bassiri, R., Bell, A., Billingsley, G., Birney, R., Blair, D., Bonilla, E., Briggs, J., Brown, D. D., Byer, R., Cao, H., Constancio, M., ... Zhao, C. (2020). A cryogenic silicon interferometer for gravitational-wave detection. Classical and Quantum Gravity, 37(16), [165003]. https://doi.org/10.1088/1361-6382/ab9143

Adhikari, R.X. ; Arai, K. ; Brooks, A.F. ; Wipf, C. ; Aguiar, O. ; Altin, P. ; Barr, B. ; Barsotti, L. ; Bassiri, R. ; Bell, A. ; Billingsley, G. ; Birney, R. ; Blair, D. ; Bonilla, E. ; Briggs, J. ; Brown, D.D. ; Byer, R. ; Cao, H. ; Constancio, M. ; Cooper, S. ; Corbitt, T. ; Coyne, D. ; Cumming, A. ; Daw, E. ; Derosa, R. ; Eddolls, G. ; Eichholz, J. ; Evans, M. ; Fejer, M. ; Ferreira, E.C. ; Freise, A. ; Frolov, V.V. ; Gras, S. ; Green, A. ; Grote, H. ; Gustafson, E. ; Hall, E.D. ; Hammond, G. ; Harms, J. ; Harry, G. ; Haughian, K. ; Heinert, D. ; Heintze, M. ; Hellman, F. ; Hennig, J. ; Hennig, M. ; Hild, S. ; Hough, J. ; Johnson, W. ; Kamai, B. ; Kapasi, D. ; Komori, K. ; Koptsov, D. ; Korobko, M. ; Korth, W.Z. ; Kuns, K. ; Lantz, B. ; Leavey, S. ; Magana-Sandoval, F. ; Mansell, G. ; Markosyan, A. ; Markowitz, A. ; Martin, I. ; Martin, R. ; Martynov, D. ; Mcclelland, D.E. ; Mcghee, G. ; Mcrae, T. ; Mills, J. ; Mitrofanov, V. ; Molina-Ruiz, M. ; Mow-Lowry, C. ; Munch, J. ; Murray, P. ; Ng, S. ; Okada, M.A. ; Ottaway, D.J. ; Prokhorov, L. ; Quetschke, V. ; Reid, S. ; Reitze, D. ; Richardson, J. ; Robie, R. ; Romero-Shaw, I. ; Route, R. ; Rowan, S. ; Schnabel, R. ; Schneewind, M. ; Seifert, F. ; Shaddock, D. ; Shapiro, B. ; Shoemaker, D. ; Silva, A.S. ; Slagmolen, B. ; Smith, J. ; Smith, N. ; Steinlechner, J. ; Strain, K. ; Taira, D. ; Tait, S. ; Tanner, D. ; Tornasi, Z. ; Torrie, C. ; Van Veggel, M. ; Vanheijningen, J. ; Veitch, P. ; Wade, A. ; Wallace, G. ; Ward, R. ; Weiss, R. ; Wessels, P. ; Willke, B. ; Yamamoto, H. ; Yap, M.J. ; Zhao, C. / A cryogenic silicon interferometer for gravitational-wave detection. In: Classical and Quantum Gravity. 2020 ; Vol. 37, No. 16.

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title = "A cryogenic silicon interferometer for gravitational-wave detection",

abstract = "{\textcopyright} 2020 IOP Publishing Ltd.The detection of gravitational waves from compact binary mergers by LIGO has opened the era of gravitational wave astronomy, revealing a previously hidden side of the cosmos. To maximize the reach of the existing LIGO observatory facilities, we have designed a new instrument able to detect gravitational waves at distances 5 times further away than possible with Advanced LIGO, or at greater than 100 times the event rate. Observations with this new instrument will make possible dramatic steps toward understanding the physics of the nearby Universe, as well as observing the Universe out to cosmological distances by the detection of binary black hole coalescences. This article presents the instrument design and a quantitative analysis of the anticipated noise floor.",

author = "R.X. Adhikari and K. Arai and A.F. Brooks and C. Wipf and O. Aguiar and P. Altin and B. Barr and L. Barsotti and R. Bassiri and A. Bell and G. Billingsley and R. Birney and D. Blair and E. Bonilla and J. Briggs and D.D. Brown and R. Byer and H. Cao and M. Constancio and S. Cooper and T. Corbitt and D. Coyne and A. Cumming and E. Daw and R. Derosa and G. Eddolls and J. Eichholz and M. Evans and M. Fejer and E.C. Ferreira and A. Freise and V.V. Frolov and S. Gras and A. Green and H. Grote and E. Gustafson and E.D. Hall and G. Hammond and J. Harms and G. Harry and K. Haughian and D. Heinert and M. Heintze and F. Hellman and J. Hennig and M. Hennig and S. Hild and J. Hough and W. Johnson and B. Kamai and D. Kapasi and K. Komori and D. Koptsov and M. Korobko and W.Z. Korth and K. Kuns and B. Lantz and S. Leavey and F. Magana-Sandoval and G. Mansell and A. Markosyan and A. Markowitz and I. Martin and R. Martin and D. Martynov and D.E. Mcclelland and G. Mcghee and T. Mcrae and J. Mills and V. Mitrofanov and M. Molina-Ruiz and C. Mow-Lowry and J. Munch and P. Murray and S. Ng and M.A. Okada and D.J. Ottaway and L. Prokhorov and V. Quetschke and S. Reid and D. Reitze and J. Richardson and R. Robie and I. Romero-Shaw and R. Route and S. Rowan and R. Schnabel and M. Schneewind and F. Seifert and D. Shaddock and B. Shapiro and D. Shoemaker and A.S. Silva and B. Slagmolen and J. Smith and N. Smith and J. Steinlechner and K. Strain and D. Taira and S. Tait and D. Tanner and Z. Tornasi and C. Torrie and {Van Veggel}, M. and J. Vanheijningen and P. Veitch and A. Wade and G. Wallace and R. Ward and R. Weiss and P. Wessels and B. Willke and H. Yamamoto and M.J. Yap and C. Zhao",

year = "2020",

month = aug,

day = "20",

doi = "10.1088/1361-6382/ab9143",

language = "English",

volume = "37",

journal = "Classical and Quantum Gravity",

issn = "0264-9381",

publisher = "IOP Publishing Ltd.",

number = "16",

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Adhikari, RX, Arai, K, Brooks, AF, Wipf, C, Aguiar, O, Altin, P, Barr, B, Barsotti, L, Bassiri, R, Bell, A, Billingsley, G, Birney, R, Blair, D, Bonilla, E, Briggs, J, Brown, DD, Byer, R, Cao, H, Constancio, M, Cooper, S, Corbitt, T, Coyne, D, Cumming, A, Daw, E, Derosa, R, Eddolls, G, Eichholz, J, Evans, M, Fejer, M, Ferreira, EC, Freise, A, Frolov, VV, Gras, S, Green, A, Grote, H, Gustafson, E, Hall, ED, Hammond, G, Harms, J, Harry, G, Haughian, K, Heinert, D, Heintze, M, Hellman, F, Hennig, J, Hennig, M, Hild, S, Hough, J, Johnson, W, Kamai, B, Kapasi, D, Komori, K, Koptsov, D, Korobko, M, Korth, WZ, Kuns, K, Lantz, B, Leavey, S, Magana-Sandoval, F, Mansell, G, Markosyan, A, Markowitz, A, Martin, I, Martin, R, Martynov, D, Mcclelland, DE, Mcghee, G, Mcrae, T, Mills, J, Mitrofanov, V, Molina-Ruiz, M, Mow-Lowry, C, Munch, J, Murray, P, Ng, S, Okada, MA, Ottaway, DJ, Prokhorov, L, Quetschke, V, Reid, S, Reitze, D, Richardson, J, Robie, R, Romero-Shaw, I, Route, R, Rowan, S, Schnabel, R, Schneewind, M, Seifert, F, Shaddock, D, Shapiro, B, Shoemaker, D, Silva, AS, Slagmolen, B, Smith, J, Smith, N, Steinlechner, J, Strain, K, Taira, D, Tait, S, Tanner, D, Tornasi, Z, Torrie, C, Van Veggel, M, Vanheijningen, J, Veitch, P, Wade, A, Wallace, G, Ward, R, Weiss, R, Wessels, P, Willke, B, Yamamoto, H, Yap, MJ & Zhao, C 2020, 'A cryogenic silicon interferometer for gravitational-wave detection', Classical and Quantum Gravity, vol. 37, no. 16, 165003. https://doi.org/10.1088/1361-6382/ab9143

A cryogenic silicon interferometer for gravitational-wave detection. / Adhikari, R.X.; Arai, K.; Brooks, A.F.; Wipf, C.; Aguiar, O.; Altin, P.; Barr, B.; Barsotti, L.; Bassiri, R.; Bell, A.; Billingsley, G.; Birney, R.; Blair, D.; Bonilla, E.; Briggs, J.; Brown, D.D.; Byer, R.; Cao, H.; Constancio, M.; Cooper, S.; Corbitt, T.; Coyne, D.; Cumming, A.; Daw, E.; Derosa, R.; Eddolls, G.; Eichholz, J.; Evans, M.; Fejer, M.; Ferreira, E.C.; Freise, A.; Frolov, V.V.; Gras, S.; Green, A.; Grote, H.; Gustafson, E.; Hall, E.D.; Hammond, G.; Harms, J.; Harry, G.; Haughian, K.; Heinert, D.; Heintze, M.; Hellman, F.; Hennig, J.; Hennig, M.; Hild, S.; Hough, J.; Johnson, W.; Kamai, B.; Kapasi, D.; Komori, K.; Koptsov, D.; Korobko, M.; Korth, W.Z.; Kuns, K.; Lantz, B.; Leavey, S.; Magana-Sandoval, F.; Mansell, G.; Markosyan, A.; Markowitz, A.; Martin, I.; Martin, R.; Martynov, D.; Mcclelland, D.E.; Mcghee, G.; Mcrae, T.; Mills, J.; Mitrofanov, V.; Molina-Ruiz, M.; Mow-Lowry, C.; Munch, J.; Murray, P.; Ng, S.; Okada, M.A.; Ottaway, D.J.; Prokhorov, L.; Quetschke, V.; Reid, S.; Reitze, D.; Richardson, J.; Robie, R.; Romero-Shaw, I.; Route, R.; Rowan, S.; Schnabel, R.; Schneewind, M.; Seifert, F.; Shaddock, D.; Shapiro, B.; Shoemaker, D.; Silva, A.S.; Slagmolen, B.; Smith, J.; Smith, N.; Steinlechner, J.; Strain, K.; Taira, D.; Tait, S.; Tanner, D.; Tornasi, Z.; Torrie, C.; Van Veggel, M.; Vanheijningen, J.; Veitch, P.; Wade, A.; Wallace, G.; Ward, R.; Weiss, R.; Wessels, P.; Willke, B.; Yamamoto, H.; Yap, M.J.; Zhao, C.

In: Classical and Quantum Gravity, Vol. 37, No. 16, 165003, 20.08.2020.

Research output: Contribution to Journal › Article › Academic › peer-review

TY - JOUR

T1 - A cryogenic silicon interferometer for gravitational-wave detection

AU - Adhikari, R.X.

AU - Arai, K.

AU - Brooks, A.F.

AU - Wipf, C.

AU - Aguiar, O.

AU - Altin, P.

AU - Barr, B.

AU - Barsotti, L.

AU - Bassiri, R.

AU - Bell, A.

AU - Billingsley, G.

AU - Birney, R.

AU - Blair, D.

AU - Bonilla, E.

AU - Briggs, J.

AU - Brown, D.D.

AU - Byer, R.

AU - Cao, H.

AU - Constancio, M.

AU - Cooper, S.

AU - Corbitt, T.

AU - Coyne, D.

AU - Cumming, A.

AU - Daw, E.

AU - Derosa, R.

AU - Eddolls, G.

AU - Eichholz, J.

AU - Evans, M.

AU - Fejer, M.

AU - Ferreira, E.C.

AU - Freise, A.

AU - Frolov, V.V.

AU - Gras, S.

AU - Green, A.

AU - Grote, H.

AU - Gustafson, E.

AU - Hall, E.D.

AU - Hammond, G.

AU - Harms, J.

AU - Harry, G.

AU - Haughian, K.

AU - Heinert, D.

AU - Heintze, M.

AU - Hellman, F.

AU - Hennig, J.

AU - Hennig, M.

AU - Hild, S.

AU - Hough, J.

AU - Johnson, W.

AU - Kamai, B.

AU - Kapasi, D.

AU - Komori, K.

AU - Koptsov, D.

AU - Korobko, M.

AU - Korth, W.Z.

AU - Kuns, K.

AU - Lantz, B.

AU - Leavey, S.

AU - Magana-Sandoval, F.

AU - Mansell, G.

AU - Markosyan, A.

AU - Markowitz, A.

AU - Martin, I.

AU - Martin, R.

AU - Martynov, D.

AU - Mcclelland, D.E.

AU - Mcghee, G.

AU - Mcrae, T.

AU - Mills, J.

AU - Mitrofanov, V.

AU - Molina-Ruiz, M.

AU - Mow-Lowry, C.

AU - Munch, J.

AU - Murray, P.

AU - Ng, S.

AU - Okada, M.A.

AU - Ottaway, D.J.

AU - Prokhorov, L.

AU - Quetschke, V.

AU - Reid, S.

AU - Reitze, D.

AU - Richardson, J.

AU - Robie, R.

AU - Romero-Shaw, I.

AU - Route, R.

AU - Rowan, S.

AU - Schnabel, R.

AU - Schneewind, M.

AU - Seifert, F.

AU - Shaddock, D.

AU - Shapiro, B.

AU - Shoemaker, D.

AU - Silva, A.S.

AU - Slagmolen, B.

AU - Smith, J.

AU - Smith, N.

AU - Steinlechner, J.

AU - Strain, K.

AU - Taira, D.

AU - Tait, S.

AU - Tanner, D.

AU - Tornasi, Z.

AU - Torrie, C.

AU - Van Veggel, M.

AU - Vanheijningen, J.

AU - Veitch, P.

AU - Wade, A.

AU - Wallace, G.

AU - Ward, R.

AU - Weiss, R.

AU - Wessels, P.

AU - Willke, B.

AU - Yamamoto, H.

AU - Yap, M.J.

AU - Zhao, C.

PY - 2020/8/20

Y1 - 2020/8/20

N2 - © 2020 IOP Publishing Ltd.The detection of gravitational waves from compact binary mergers by LIGO has opened the era of gravitational wave astronomy, revealing a previously hidden side of the cosmos. To maximize the reach of the existing LIGO observatory facilities, we have designed a new instrument able to detect gravitational waves at distances 5 times further away than possible with Advanced LIGO, or at greater than 100 times the event rate. Observations with this new instrument will make possible dramatic steps toward understanding the physics of the nearby Universe, as well as observing the Universe out to cosmological distances by the detection of binary black hole coalescences. This article presents the instrument design and a quantitative analysis of the anticipated noise floor.

AB - © 2020 IOP Publishing Ltd.The detection of gravitational waves from compact binary mergers by LIGO has opened the era of gravitational wave astronomy, revealing a previously hidden side of the cosmos. To maximize the reach of the existing LIGO observatory facilities, we have designed a new instrument able to detect gravitational waves at distances 5 times further away than possible with Advanced LIGO, or at greater than 100 times the event rate. Observations with this new instrument will make possible dramatic steps toward understanding the physics of the nearby Universe, as well as observing the Universe out to cosmological distances by the detection of binary black hole coalescences. This article presents the instrument design and a quantitative analysis of the anticipated noise floor.

U2 - 10.1088/1361-6382/ab9143

DO - 10.1088/1361-6382/ab9143

M3 - Article

VL - 37

JO - Classical and Quantum Gravity

JF - Classical and Quantum Gravity

SN - 0264-9381

IS - 16

M1 - 165003

ER -