Demonstration of a switchable damping system to allow low-noise operation of high-Q low-mass suspension systems
Low-mass suspension systems with high-Q pendulum stages are used to enable quantum radiation pressure noise limited experiments. Utilizing multiple pendulum stages with vertical blade springs and materials with high-quality factors provides attenuation of seismic and thermal noise; however, damping...
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| creator | Hennig, Jan-Simon Barr, Bryan W Bell, Angus S Cunningham, William Danilishin, Stefan L Dupej, Peter Graf, Christian Hough, James Huttner, Sabina H Jones, Russell Leavey, Sean S Pascucci, Daniela Sinclair, Martin Sorazu, Borja Spencer, Andrew Steinlechner, Sebastian Strain, Kenneth A Wright, Jennifer Zhang, Teng Hild, Stefan |
| description | Low-mass suspension systems with high-Q pendulum stages are used to enable quantum radiation pressure noise limited experiments. Utilizing multiple pendulum stages with vertical blade springs and materials with high-quality factors provides attenuation of seismic and thermal noise; however, damping of these high-Q pendulum systems in multiple degrees of freedom is essential for practical implementation. Viscous damping such as eddy-current damping can be employed, but it introduces displacement noise from force noise due to thermal fluctuations in the damping system. In this paper we demonstrate a passive damping system with adjustable damping strength as a solution for this problem that can be used for low-mass suspension systems without adding additional displacement noise in science mode. We show a reduction of the damping factor by a factor of 8 on a test suspension and provide a general optimization for this system. |
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Utilizing multiple pendulum stages with vertical blade springs and materials with high-quality factors provides attenuation of seismic and thermal noise; however, damping of these high-Q pendulum systems in multiple degrees of freedom is essential for practical implementation. Viscous damping such as eddy-current damping can be employed, but it introduces displacement noise from force noise due to thermal fluctuations in the damping system. In this paper we demonstrate a passive damping system with adjustable damping strength as a solution for this problem that can be used for low-mass suspension systems without adding additional displacement noise in science mode. 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| source | American Physical Society Journals; Ghent University Academic Bibliography |
| subjects | Physics and Astronomy |
| title | Demonstration of a switchable damping system to allow low-noise operation of high-Q low-mass suspension systems |
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