From seismic noise to ocean wave parameters: General methods and validation

Ardhuin, Fabrice; Balanche, Abel; Stutzmann, É.; Obrebski, Mathias

doi:10.1029/2011jc007449

Cited by 70 publications

(78 citation statements)

References 58 publications

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“…In summary, microseismic records of vertical ground velocity from land-based seismological stations can be used to delineate the spring and fall transitions in the northern California Current upwelling system where microseisms are dominated by the double frequency wave reflection generation mechanism in winter [Ardhuin et al, 2011[Ardhuin et al, , 2012. By extension, it might be possible to use the global network of seismic stations to …”

Section: Resultsmentioning

confidence: 99%

“…Numerical simulations of wind-generated microseisms by Ardhuin et al [2011Ardhuin et al [ , 2012 show that the wave reflection mechanism generally dominates in eastern boundary regions and is particularly dominant off central California in winter. Microseisms recorded at seismological stations typically represent sources within a few hundred kilometers of the coast [Bromirski et al, 2013].…”

Section: Wave-generated Microseismsmentioning

confidence: 99%

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Continental microseismic intensity delineates oceanic upwelling timing along the west coast of North America

Thomson

Martin

Davis

et al. 2014

Geophysical Research Letters

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The biological productivity of coastal upwelling regions undergoes marked interannual variability as marine ecosystems respond to changes in the prevailing winds. Determination of the principal metrics that define the upwelling cycle-the spring transition, when ocean conditions switch from downwelling-to upwelling-favorable, and the Fall Transition, when conditions return to downwelling-favorable-is essential for understanding changes in coastal productivity. Here we demonstrate that upwelling in the northern California Current System may be delineated by changes in microseismic activity recorded at a broadband seismological station in southwestern British Columbia. Observed high correlation between microseismic intensity and offshore bottom pressure fluctuations at~0.2 Hz confirms a direct link to regional wind-wave generation. Comparison of transition times derived from coincident 20 year records of microseismic intensity and alongshore wind stress for the British Columbia-Oregon coast suggests that seismically derived times may be more representative of coastal upwelling than times derived using traditional methods.

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Section: Resultsmentioning

confidence: 99%

Section: Wave-generated Microseismsmentioning

confidence: 99%

Continental microseismic intensity delineates oceanic upwelling timing along the west coast of North America

Thomson

Martin

Davis

et al. 2014

Geophysical Research Letters

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“…Seismic noise: Based on the numerical noise mode of have explained how loud seismic noise events can be associated with relatively moderate sea states. That understanding has been further exploited by Ardhuin et al (2012a) to propose a generic method for estimating ocean wave spectra from seismic noise data.…”

Section: Discussionmentioning

confidence: 99%

Wave Dissipation and Balance - NOPP Wave Project

Ardhuin¹

2012

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Award Number: N00014-10-1-0383 http://wwz.ifremer.fr/iowaga LONG-TERM GOALSWind-generated waves play a prominent role at the interfaces of the ocean with the atmosphere, land and solid Earth. Waves also define in many ways the appearance of the ocean seen by remote-sensing instruments. Beyond these geophysical aspects, waves also affect human activities at sea and on the coast. The long-term goals of this research are to obtain a better understanding of the physical processes that affect ocean surface waves and their interactions with ocean currents and turbulence, the atmosphere, seismic waves, sediments and remote sensing systems, and to improve our forecasting and hindcasting capacity of these phenomena from the global ocean to the nearshore scale. OBJECTIVES• Observe and parameterize the dissipation of ocean waves due to breaking or wind-wave interactions• Advance spectral wave modeling at all (global to beach) scales in a unified framework, in terms of parameterization and numerical developments• Help the application of wave models to new problems (upper ocean mixing and surface drift, use of seismic noise data, air-sea gas exchange ...) and use these applications for feedback on the wave model quality APPROACH AND WORK PLANBy combining theoretical advances with numerical models, remote sensing and field observations, we investigate the physical processes that affect wind-generated ocean gravity waves, and provide constraints on their parameterization in spectral models. The various dissipative processes that contribute to the spectral wave evolution are isolated by considering geophysical situations in which they are dominant: the long-distance swell propagation in the case of air-sea friction, the evolution of swells on shallow continent shelves in the case of bottom friction, the energy level in the spectral tail in the case of cumulative breaking effects, and the breaking statistics of waves. These require the 1

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“…Both Bromirski [6] and Ardhuin et al [7] determined ocean wave heights at a buoy located off the Californian coast using seismic data from a single inland station quite successfully. Empirical methods were used [6] for this inversion which required time series information for the buoy including directional properties of the ocean wave field and microseism source location.…”

Section: A Seismic Datamentioning

confidence: 99%

“…More recently a model of microseism noise generation and propagation was introduced to determine possible source locations and, using empirical methods to retrieve the ocean wavefield frequency spectrum from seismic noise spectrum it is possible to estimate SWH at that buoy location [7].…”

Section: B Previous Workmentioning

confidence: 99%

Wave height quantification using land based seismic data with grammatical evolution

Donne

Nicolau

Bean

et al. 2014

2014 IEEE Congress on Evolutionary Computation (CEC)

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Abstract-Accurate, real time, continuous ocean wave height measurements are required for the initialisation of ocean wave forecast models, model hindcasting, and climate studies. These measurements are usually obtained using in situ ocean buoys or by satellite altimetry, but are sometimes incomplete due to instrument failure or routine network upgrades. In such situations, a reliable gap filling technique is desirable to provide a continuous and accurate ocean wave field record. Recorded on a land based seismic network are continuous seismic signals known as microseisms. These microseisms are generated by the interactions of ocean waves and will be used in the estimation of ocean wave heights. Grammatical Evolution is applied in this study to generate symbolic models that best estimate ocean wave height from terrestrial seismic data, and the best model is validated against an Artificial Neural Network. Both models are tested over a five month period of 2013, and an analysis of the results obtained indicates that the approach is robust and that it is possible to estimate ocean wave heights from land based seismic data.

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From seismic noise to ocean wave parameters: General methods and validation

Cited by 70 publications

References 58 publications

Continental microseismic intensity delineates oceanic upwelling timing along the west coast of North America

Continental microseismic intensity delineates oceanic upwelling timing along the west coast of North America

Wave Dissipation and Balance - NOPP Wave Project

Wave height quantification using land based seismic data with grammatical evolution

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