Composite mirror suspensions development status and directions ELiTES activity interim report JGW-G1201174.

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Presentation transcript:

Composite mirror suspensions development status and directions ELiTES activity interim report JGW-G

The idea A fresh approach to the design of low thermal noise mirror suspensions for KAGRA and ET

Key features: Composite structure Purely Compressive joints No shear noise No need for bonding Easy replacements Easily scalable to larger masses

Flexure Key features: Silicon flexures Intrinsic Q-factor >10 8 Thermo-elastic >10 6 Diluted Q-factor >10 9 Before cryo gain ! Many Machining options available

Flexure structure Ultra-Sound Machined structure Etching of the flexure surface Expected to increase the break point >1GPa

Flexure structure Thin, short, etched flexure smallflexure aspect ratio Large thermal conductance

Chao Shiu laboratory, Taiwan Silicon cantilever with KOH wet etching 4” un-doped double-side polished (001) silicon wafer, 500um thickness etched down to 92 and 52 µm loss measured from residual gas mm 10 mm 92 μm or 52 μm 34 mm 0.35mm 500 μm 5.5mm Frequency=59.04 (Hz) φ measurement = 1.4*10 -6 Time(sec) Amplitude Decay Time = (s) Silicon cantilever (d=52um) Amplitude(V) Original Data Decay Time = (s) φ measurement = 4.3*10 -6 Frequency = (Hz) Silicon cantilever (d=92um)

Thermo-elastic 59 Hz loss angle predicted (T.E.) measured (-) residual gas loss angle measured => 100% Thermoelastic limited ! ! ! Frequency=59.04 (Hz) φ measurement = 1.4*10 -6 Time(sec) Amplitude Decay Time = (s) Silicon cantilever (d=52um)

Kenji’s Q-factor measurements Measurement on a mirror substrate 10 8 lower limit

Ribbons Key features: Compression joint attachment Machined-polished Sapphire ribbons High quality sapphire High quality surface finish (sub-phonon defect size) = > High thermal conductivity !

Conductance budget Preliminary conductance budget from Sakakibara with 1 W load Thin ribbon responsible for bulk of loss ! ! ! Plenty of space for parametric optimization

Mirror attachment Key features: Mini-alcoves (low volume machining) Machining before coating deposition Minimize substrate induced stress Recessed attachment, Low vulnerability No bonding shear noise No flats, 100% of mirror surfaceavailable

Connections Key features: Purely compressive joints Sub-  m, Gallium gaskets + direct contact Complete elimination of stick and slip noise Perfect heat conductivity Easy replaceability

Springs Key features: Silicon springs Defects etched away Allowable surface stress < 1 GPa (to be confirmed) Elimination of vertical suspension thermal noise (necessary due to KAGRA’s tunnel tilt)

NIKHEF test Produce a number od samples Test and see

Etched Silicon cantilever blades Etch the bending area Leave thick section for clamping and for fiber connection With 0.15 Gpa Only limited flexure possible With >1GPa large deflection

Larger stresses possible? MEM sensors operating at 1.4 GPa, ~ 10 times higher limit! Is etching eliminating surface defect and therefore causing the larger strength? if YES, large bends possible! Lower frequency bounce modes

Key technologies: Ultrasound machining of sapphire and silicon Magneto-rheological Finishing (QED) Silicon etching to eliminate defects

Why Gallium Indium proved extremely effective to eliminate friction noise in compression joints (Vladimir Braginsky) Melts at relatively high temperature May need heating mirror to more than 160 o C for disassembly

Indium vs. Gallium

Violin mode elimination Fiber-fed Red-shifted Fabry-Perot Can cool violin modes to mK level Same for Parametric Instabilities)

What was done Discussed Ultra-Sound Machining technology capabilities and limitation with Mack Interactively advanced design Optimized machining procedures to physics requirements Design optimization ongoing

To do list FE simulation GWINC simulations Test machining Test assembly Conductivity Q-factors Gallium..... Test effective break point – Etched not etched – doped-not doped – Different axis orientation – tension

Development target Going from strawman to final design of cryo suspensions for KAGRA mirrors NIKHEF volunteered to lead, provide most of parts for this R&D stage, perform tests Alessandro Bertolini co-ordinating this R&D But of course many contributions are needed – Fracture measurements – Q-measurements – Thermal measurements (UTB?) –...