Excess mechanical loss associated with dielectric mirror coatings on test masses in interferometric gravitational wave detectors

被引：76

作者：

Crooks, DRM ^{[1
]}

Sneddon, P

Cagnoli, G

Hough, J

Rowan, S

Fejer, MM

Gustafson, E

Route, R

Nakagawa, N

Coyne, D

Harry, GM

Gretarsson, AM

机构：

[1] Univ Glasgow, Dept Phys & Astron, Glasgow G12 8QQ, Lanark, Scotland

[2] Stanford Univ, Edward L Ginzton Lab, Stanford, CA 94305 USA

[3] Iowa State Univ, Inst Phys Res & Technol, Ctr Nondestruct Evaluat, Ames, IA 50011 USA

[4] CALTECH, LIGO Lab, Pasadena, CA 91125 USA

[5] MIT, LIGO Lab, Cambridge, MA 02139 USA

[6] Syracuse Univ, Dept Phys, Syracuse, NY 13244 USA

来源：

CLASSICAL AND QUANTUM GRAVITY | 2002年 / 19卷 / 05期

关键词：

D O I：

10.1088/0264-9381/19/5/304

中图分类号：

P1 [天文学];

学科分类号：

0704 ;

摘要：

Interferometric gravitational wave detectors use mirrors whose substrates are formed from materials of low intrinsic mechanical dissipation. The two most likely choices for the test masses in future advanced detectors are fused silica or sapphire (Rowan S et al 2000 Phys. Lett. A 265 5). These test masses must be coated to form mirrors, highly reflecting at 1064 nm. We have measured the excess mechanical losses associated with adding dielectric coatings to substrates of fused silica and calculated the effect of the excess loss on the thermal noise in an advanced interferometer.

引用

页码：883 / 896

页数：14

共 22 条

[1] The thermal noise limit to the Virgo sensitivity [J].

Amico, P ;

Carbone, L ;

Cattuto, C ;

Gammaitoni, L ;

Marchesoni, F ;

Mischianti, R ;

Punturo, M ;

Travasso, F ;

Vocca, H .

CLASSICAL AND QUANTUM GRAVITY, 2001, 18 (19) :4127-4131

[2] Thermal noise in mirrors of interferometric gravitational wave antennas [J].

Bondu, F ;

Hello, P ;

Vinet, JY .

PHYSICS LETTERS A, 1998, 246 (3-4) :227-236

[3]

FRITSCHEL P, 2001, ADV LIGO SYSTEMS DES

[4] THERMALLY EXCITED VIBRATIONS OF THE MIRRORS OF LASER INTERFEROMETER GRAVITATIONAL-WAVE DETECTORS [J].

GILLESPIE, A ;

RAAB, F .

PHYSICAL REVIEW D, 1995, 52 (02) :577-585

[5] Pendulum mode thermal noise in advanced interferometers: a comparison of fused silica fibers and ribbons in the presence of surface loss [J].

Gretarsson, AM ;

Harry, GM ;

Penn, SD ;

Saulson, PR ;

Startin, WJ ;

Rowan, S ;

Cagnoli, G ;

Hough, J .

PHYSICS LETTERS A, 2000, 270 (3-4) :108-114

[6] Internal thermal noise in the LIGO test masses: A direct approach [J].

Levin, Y .

PHYSICAL REVIEW D, 1998, 57 (02) :659-663

[7] Thermoelastic noise and homogeneous thermal noise in finite sized gravitational-wave test masses [J].

Liu, YT ;

Thorne, KS .

PHYSICAL REVIEW D, 2000, 62 (12) :1-10

[8] AN INVESTIGATION OF LIMITATIONS TO QUALITY FACTOR MEASUREMENTS OF SUSPENDED MASSES DUE TO RESONANCES IN THE SUSPENSION WIRES [J].

LOGAN, JE ;

ROBERTSON, NA ;

HOUGH, J .

PHYSICS LETTERS A, 1992, 170 (05) :352-358

[9] EXPERIMENTAL STUDY OF VIBRATIONS OF SOLID ISOTROPIC ELASTIC CYLINDERS [J].

MCMAHON, GW .

JOURNAL OF THE ACOUSTICAL SOCIETY OF AMERICA, 1964, 36 (01) :85-+

[10]

Musikant S., 2020, OPTICAL MAT INTRO SE

← 1 2 3 →