Related references
Note: Only part of the references are listed.Principles of wide bandwidth acoustic detectors and the single-mass dual detector
Michele Bonaldi et al.
PHYSICAL REVIEW D (2006)
3-Mode detection for widening the bandwidth of resonant gravitational wave detectors
L Baggio et al.
PHYSICAL REVIEW LETTERS (2005)
LTP interferometer - noise sources and performance
D Robertson et al.
CLASSICAL AND QUANTUM GRAVITY (2005)
Transverse vibration analysis and measurement for the piezoceramic annular plate with different boundary conditions
CH Huang
JOURNAL OF SOUND AND VIBRATION (2005)
A loss mechanism study of a very high Q silicon micromechanical oscillator -: art. no. 023524
X Liu et al.
JOURNAL OF APPLIED PHYSICS (2005)
Temperature dependence of the force sensitivity of silicon cantilevers
U Gysin et al.
PHYSICAL REVIEW B (2004)
The intrinsic mechanical loss factor of hydroxy-catalysis bonds for use in the mirror suspensions of gravitational wave detectors
PH Sneddon et al.
CLASSICAL AND QUANTUM GRAVITY (2003)
Energy transfer model for squeeze-film air damping in low vacuum
MH Bao et al.
JOURNAL OF MICROMECHANICS AND MICROENGINEERING (2002)
The GEO 600 gravitational wave detector
B Willke et al.
CLASSICAL AND QUANTUM GRAVITY (2002)
Noise measurements and optimization of the high sensitivity capacitive transducer of AURIGA
A Marin et al.
CLASSICAL AND QUANTUM GRAVITY (2002)
Sub-attonewton force detection at millikelvin temperatures
HJ Mamin et al.
APPLIED PHYSICS LETTERS (2001)
Wideband dual sphere detector of gravitational waves
M Cerdonio et al.
PHYSICAL REVIEW LETTERS (2001)
Measurement of the mechanical loss of crystalline samples using a nodal support
K Numata et al.
PHYSICS LETTERS A (2001)
Normal modes of a Si(100) double-paddle oscillator
CL Spiel et al.
REVIEW OF SCIENTIFIC INSTRUMENTS (2001)
Measurement of the intrinsic mechanical loss of low-loss samples using a nodal support
K Numata et al.
PHYSICS LETTERS A (2000)