Estimation of the effect of nonisotropically distributed energy on the apparent arrival time in correlations

Froment, B.; Campillo, Míchel; Roux, Philippe; Gouédard, Pierre; Verdel, Arie; Weaver, Richard L.

doi:10.1190/1.3483102

Cited by 175 publications

(157 citation statements)

References 39 publications

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“…Finally, the phase of the symmetric part of the cross-correlation, that is, [ C S ], is largely unaffected by the non-uniformity of P(θ ). This suggests that phase velocity measurements may give results that only slightly deviate from the 'real' phase velocity and is in line with the data analyses by Gouédard et al (2008) and Froment et al (2010).…”

Section: Experiments 3: Non-uniform Illuminationsupporting

confidence: 70%

“…Our results show that multiple scattering mitigates the effect of the source distribution on the amplitude of the cross-correlation; this has been shown for the phase of the cross-correlation previously (Froment et al 2010;Sens-Schönfelder & Wegler 2011). Specifically, we show that the spatially and azimuthally averaged cross-spectrum decays exponentially in case of a purely elastic scattering medium illuminated uniformly from all angles.…”

Section: Discussion a N D C O N C L U S I O Nmentioning

confidence: 57%

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On the estimation of attenuation from the ambient seismic field: inferences from distributions of isotropic point scatterers

Weemstra¹,

Snieder

Boschi

2015

Geophys. J. Int.

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S U M M A R YCross-correlation of ambient seismic noise recorded by two seismic stations may result in an estimate of the Green's function between those two receivers. Several authors have recently attempted to measure attenuation based on these interferometric, receiver-receiver surface waves. By now, however, it is well established that the loss of coherence of the crosscorrelation as a function of space depends strongly on the excitation of the medium. In fact, in a homogeneous dissipative medium, uniform excitation is required to correctly recover attenuation. Applied to fundamental-mode ambient seismic surface waves, this implies that the cross-correlation will decay at the local attenuation rate only if noise sources are distributed uniformly on the Earth's surface. In this study we show that this constraint can be relaxed in case the observed loss of coherence is due to multiple scattering instead of dissipation of energy. We describe the scattering medium as an effective medium whose phase velocity and rate of attenuation are a function of the scatterer density and the average strength of the scatterers. We find that the decay of the cross-correlation in the effective medium coincides with the local attenuation of the effective medium in case the scattering medium is illuminated uniformly from all angles. Consequently, uniform excitation is not a necessary condition for the correct retrieval of scattering attenuation. We exemplify the implications of this finding for studies using the spectrally whitened cross-correlation to infer subsurface attenuation.Key words: Surface waves and free oscillations; Seismic attenuation; Theoretical seismology; Wave scattering and diffraction. I N T RO D U C T I O NIt is now generally accepted that the cross-correlation of recordings made by two receivers is related to (and can in practice be treated as an approximation of) the Green's function at one of these receivers position if there were an impulsive source at the other. The first successful application to the solid Earth is due to Campillo & Paul (2003) who used earthquake coda to obtain empirical Green's functions. Shapiro & Campillo (2004) showed that broad-band Rayleigh waves emerge by simple cross-correlation of continuous recordings of ambient seismic noise. The latter finding holds in media other than the Earth: for example, helioseismology (Duvall et al. 1993), underwater acoustics (Roux & Fink 2003), ultrasonics (Weaver & Lobkis 2001, 2002, engineering (Snieder & Şafak 2006;Kohler et al. 2007) and infrasound (Haney 2009 the Earth's ambient seismic field use ambient seismic surface wave energy: ocean gravity waves, the main source of ambient seismic noise on Earth, excite surface waves much more effectively than other seismic phases. The process of generating new responses by cross-correlation of ambient seismic signal is often referred to as 'passive seismic interferometry'.Recently, several researchers have focused on estimating attenuation based on interferometric measurements of surface waves (Prieto e...

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Section: Experiments 3: Non-uniform Illuminationsupporting

confidence: 70%

Section: Discussion a N D C O N C L U S I O Nmentioning

confidence: 57%

On the estimation of attenuation from the ambient seismic field: inferences from distributions of isotropic point scatterers

Weemstra¹,

Snieder

Boschi

2015

Geophys. J. Int.

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“…The detailed processing that lead to these correlation functions can be found in Boué et al (2014). The use of one year of continuous data, and the symmetric part (stack of the positive and negative lag time) of the correlation functions strongly reduced potential bias due to uneven noise source distributions (Froment et al 2010;Kimman & Trampert 2010). In total, 593 stations were used (i.e.…”

Section: Noise Correlationsmentioning

confidence: 99%

Arrival angle anomalies of Rayleigh waves observed at a broadband array: a systematic study based on earthquake data, full waveform simulations and noise correlations

et al. 2015

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S U M M A R YDeviation of seismic surface waves from the great-circle between source and receiver is illustrated by the anomalies in the arrival angle, that is the difference between the observed backazimuth of the incident waves and the great-circle. Such arrival angle anomalies have been known for decades, but observations remain scattered. We present a systematic study of arrival angle anomalies of fundamental mode Rayleigh waves (20-100 s period interval) from 289 earthquakes and recorded by a broadband network LAPNET, located in northern Finland. These observations are compared with those of full waveform synthetic seismograms for the same events, calculated in a 3-D Earth and also compared with those of seismograms obtained by ambient noise correlation. The arrival angle anomalies for individual events are complex, and have significant variations with period. On average, the mean absolute deviation decreases from ∼9 • at 20 s period to ∼3 • at 100 s period. The synthetic seismograms show the same evolution, albeit with somewhat smaller deviations. While the arrival angle anomalies are fairly well simulated at long periods, the deviations at short periods are very poorly modelled, demonstrating the importance of the continuous improvement of global crustal models. At 20-30 s period, both event data and numerical simulations have strong multipathing, and relative amplitude changes between different waves will induced differences in deviations between very closely located events. The source mechanism has only limited influence on the deviations, demonstrating that they are directly linked to propagation effects, including near-field effects in the source area. This observation is confirmed by the comparison with seismic noise correlation records, that is where the surface waves correspond to those emitted by a point source at the surface, as the two types of observations are remarkably similar in the cases where earthquakes are located close to seismic stations. This agreement additionally confirms that the noise correlations capture the complex surface wave propagation.

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“…Using the work of Weaver et al (2009) andFroment et al (2010), we estimate the theoretical phase shifts predicted by a given azimuthal distribution of the noise energy (ADNE). We find that a simple synthetic ADNE made of two Gaussian functions centered at 150°and 300°(the principal back azimuths of the noise directivity observed in Figure 3) reproduces the main features (sinusoidal shape and amplitudes) of the phase shifts measured on real data.…”

Section: Impact Of a Directive Noisementioning

confidence: 99%

“…The consequences of violating these assumptions have been studied theoretically and numerically using synthetic data (Weaver et al 2009;Froment et al 2010). Although the seismic noise distribution on Earth is rarely homogeneous in time and space, the CCFs approximate Green's functions correctly if the inter-station distances are long and the azimuthal distribution of the noise is smooth.…”

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confidence: 99%

Characterization of ambient seismic noise near a deep geothermal reservoir and implications for interferometric methods: a case study in northern Alsace, France

et al. 2015

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Background: Ambient noise correlation techniques are of growing interest for imaging and monitoring deep geothermal reservoirs. They are simple to implement and can be performed continuously to follow the evolution of the reservoir at low cost. However, these methods rely on assumptions of spatial and temporal uniformity of seismic noise sources. Violating them can result in misinterpretation of seismic velocities owing to preferential noise propagation directions.

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Estimation of the effect of nonisotropically distributed energy on the apparent arrival time in correlations

Cited by 175 publications

References 39 publications

On the estimation of attenuation from the ambient seismic field: inferences from distributions of isotropic point scatterers

On the estimation of attenuation from the ambient seismic field: inferences from distributions of isotropic point scatterers

Arrival angle anomalies of Rayleigh waves observed at a broadband array: a systematic study based on earthquake data, full waveform simulations and noise correlations

Characterization of ambient seismic noise near a deep geothermal reservoir and implications for interferometric methods: a case study in northern Alsace, France

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