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Paper detail

Nanofabricated torsion pendulums for tabletop gravity experiments

Measurement of mutual gravitation on laboratory scales is an outstanding challenge and a prerequisite to probing theories of quantum gravity. A leading technology in tabletop gravity experiments is the torsion balance, with limitations due to thermal decoherence. Recent demonstrations of lithographically defined suspensions in thin-film silicon nitride with macroscale test masses suggest a path forward, as torsion pendulums dominated by gravitational stiffness may achieve higher mechanical quality factors through dilution of material losses. Here we demonstrate a 250 micron by 5 mm by 1.8 micron torsion fiber supporting 87 grams and forming a Cavendish-style torsion pendulum with tungsten test masses that -- to our knowledge -- is the largest thin-film silicon-nitride-based oscillator to date. Torsion pendulums with thin-film, nanofabricated suspensions provide a test bed for near-term tabletop experiments probing classical and quantum gravitational interaction between oscillators.

preprint2026arXivOpen access
Jack ManleyCharles A. CondosZachary FegleyGayathrini PremawardhanaThomas BsaibesJacob M. TaylorDalziel J. WilsonJon R. Pratt
physics.ins-detgr-qcquant-ph
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Jack ManleyCharles A. CondosZachary FegleyGayathrini PremawardhanaThomas BsaibesJacob M. TaylorDalziel J. WilsonJon R. Pratt

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