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arxiv 2305.01468 v1 pith:7JQ674N6 submitted 2023-05-02 physics.geo-ph physics.comp-phphysics.ins-detphysics.optics

Long-range fiber-optic earthquake sensing by active phase noise cancellation

classification physics.geo-ph physics.comp-phphysics.ins-detphysics.optics
keywords earthquakesensingfrequencymetrologicalphaseactivecancellationcompensation
verification ladder T0 review T1 audit T2 compute T3 formal T4 reserved
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We present a long-range fiber-optic environmental deformation sensor based on active phase noise cancellation (PNC) in metrological frequency dissemination. PNC sensing exploits recordings of a compensation frequency that is commonly discarded. Without the need for dedicated measurement devices, it operates synchronously with metrological services, suggesting that existing phase-stabilized metrological networks can be co-used effortlessly as environmental sensors. The compatibility of PNC sensing with inline amplification enables the interrogation of cables with lengths beyond 1000 km, making it a potential contributor to earthquake detection and early warning in the oceans. Using spectral-element wavefield simulations that accurately account for complex cable geometry, we compare observed and computed recordings of the compensation frequency for a magnitude 3.9 earthquake in south-eastern France and a 123 km fiber link between Bern and Basel, Switzerland. The match in both phase and amplitude indicates that PNC sensing can be used quantitatively, for example, in earthquake detection and characterization.

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