Estimating quality factor and mean grain size of sediments from high-resolution marine seismic data

Pinson, L.J.W.; Henstock, T.; Dix, Justin K.; Bull, Jonathan M.

doi:10.1190/1.2937171

Cited by 70 publications

(71 citation statements)

References 32 publications

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“…Malinkowski et al, 2011;Kamei & Pratt, 2013); furthermore, constraining Qs from marine seismic data would require isolating converted S-waves. In this case study, the sensitivity to Q is further limited by the large-scale high quality factor of the fine-grained, cohesive sediments that form the dipping beds (Pinson et al, 2008;Malinkowski et al, 2011), which limits the change in waveform due to attenuation. However, the large-scale, high precision, Qp model of Pinson et al (2008) accounts for the intrinsic attenuation of energy, enhancing the stability of the inversion and the reliability of the solution.…”

Section: G Provenzano Et Almentioning

confidence: 99%

“…Previous geophysical data available in the area comprise acoustic quality factor Qp (Pinson et al, 2008), and long-wavelength P-wave velocity field from Migration Velocity Analysis (MVA) (Pinson, 2009), along with lithology, porosity and density log-measurements of a proximal sediment core. Seismic to log calibration identifies a 1-to-3 meters thick gravel layer, with low Qp (c. 50), high P-wave velocity and density; it overlays, separated by an erosive unconformity, an over-consolidated clay-dominated layered sediment sequence, with high Qp (c. 150) and acoustic velocity.…”

Section: Setting and Data Overviewmentioning

confidence: 99%

“…The latter is an unusually low value for shallow marine sediments, but is required due to the over-consolidation; tests run with higher average Poisson's ratio resulted in higher data misfit. Although we invert here for the elastic parameters, the forward model includes a long-wavelength Qp model determined using the spectral ratio method from near-offset Boomer and Chirp over the sediment sequence (Pinson et al, 2008); the Qs model is derived from Qp using, in the absence of other information, a high-Q empirical relationship between compressional and shear attenuation, i.e. Qs = 4/9Qp (Aki & Richards, 2002).…”

Section: Setting and Data Overviewmentioning

confidence: 99%

“…The Qp macro-model estimated using the spectral ratio method (Pinson et al, 2008) and the derived Qs were included in the forward model, in particular to account for the strong intrinsic attenuation within the top low-Qp gravel layer. Although a high-fidelity attenuation model would further improve the characterisation of the sediment column, a reliable and precise wavelengthscale Qp-model is difficult to achieve: in the high Qp limit there is little attenuation per wavelength, and in the low Qp limit the energy is unable to propagate.…”

Section: G Provenzano Et Almentioning

confidence: 99%

“…Over the last few years, quantitative interpretation techniques have started to be applied also to near-surface seismic data in order to remotely derive decimetric resolution shallow sediment physical properties in terms of reflection coefficient and acoustic quality factor (Bull et al, 1998;Pinson et al, 2008;Vardy et al, 2012;Cevatoglu et al, 2015). Holland & Dettmer (2013) used the angle-dependent reflection amplitude as a function of frequency to derive physical properties layering and gradients within the shallow sediments.…”

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confidence: 99%

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Pre-stack full waveform inversion of ultra-high-frequency marine seismic reflection data

Provenzano

Vardy

Henstock

2017

Geophysical Journal International

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SUMMARYThe full waveform inversion (FWI) of seismic reflection data aims to reconstruct a detailed physical properties model of the subsurface, fitting both the amplitude and traveltime of the reflections generated at physical discontinuities in the propagation medium. Unlike reservoirscale seismic exploration, where seismic inversion is a widely adopted remote characterisation tool, ultra high frequency (UHF, 0.2-4.0 kHz) multi-channel marine reflection seismology is still most often limited to a qualitative interpretation of the reflections' architecture. Here we propose an elastic full waveform inversion methodology, custom-tailored for pre-stack UHF marine data in vertically heterogeneous media to obtain a decimetric-scale distribution of Pimpedance, density and Poisson's ratio within the shallow sub-seabed sediments. We address the deterministic multi-parameter inversion in a sequential fashion. The complex trace instantaneous phase is first inverted for the P-wave velocity to make-up for the lack of low-frequency in the data and reduce the non-linearity of the problem. This is followed by a short-offset Pimpedance optimisation and a further step of full offset range Poisson's ratio inversion. Provided that the seismogram contains wide reflection angles (> 40 degrees), we show that it is possible to invert for density and decompose a-posteriori the relative contribution of P-wave velocity and density to the P-impedance. A broad range of synthetic tests is used to prove the potential of the methodology and highlights sensitivity issues specific to UHF seismic. An example application to real data is also presented. In the real case, trace normalisation is applied to minimise the systematic error deriving from an inaccurate source wavelet estimation. G. Provenzano et al.The inverted model for the top 15 meters of the sub-seabed agrees with the local lithological information and core-log data. Thus we can obtain a detailed remote characterisation of the shallow sediments using a multi-channel sub-bottom profiler within a reasonable computing cost and with minimal pre-processing. This has the potential to reduce the need of extensive geotechnical coring campaigns.

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Section: G Provenzano Et Almentioning

confidence: 99%

Section: Setting and Data Overviewmentioning

confidence: 99%

Section: Setting and Data Overviewmentioning

confidence: 99%

Section: G Provenzano Et Almentioning

confidence: 99%

mentioning

confidence: 99%

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Pre-stack full waveform inversion of ultra-high-frequency marine seismic reflection data

Provenzano

Vardy

Henstock

2017

Geophysical Journal International

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Near‐shore geophysical and geotechnical investigations in support of the Trieste Marine Terminal extension

Masoli¹,

Petronio

Gordini

et al. 2020

Near Surface Geophysics

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A B S T R A C TThe Port of Trieste is an international hub for land and sea trade with the dynamic markets of central and eastern Europe. Thanks to its deep natural draft (about 18 m), the modern high-capacity vessels can moor to the piers. In view of the foreseen increase in maritime traffic, this harbour is undergoing modernization in order to improve the commercial traffic capability. In this expansion plan, the container Trieste Marine Terminal, Pier VII, is seeking an extension by about 200 m. In support of this feasibility study, multidisciplinary data acquisition was conducted in order to characterize the seabed, the sub-bottom sediments and the bedrock (flysch formation) in front of the Trieste Marine Terminal. The acquisition of high-resolution swath bathymetry, side-scan sonar and magnetometer data allowed a detailed analysis of the seabed conditions from an environmental and safety perspective. High-resolution seismic reflection data enabled us to characterize the Plio-Quaternary soft sediments and the underlying bedrock. A static underwater refraction survey was performed using hydrophone array deployed on the sea bottom to obtain seismic velocities and to achieve a reliable time-to-depth conversion of reflection seismic data by first-arrival tomographic inversion. In addition to geophysical investigations, 11 offshore boreholes were drilled for detailed logging. In situ standard penetration tests were performed on core samples with the use of a pocket penetrometer and pocket vane in order to obtain uniaxial compressive strength, undrained shear strength and undrained cohesion values, and assess the cohesive soils. During drilling, 17 undisturbed samples and 12 semi-disturbed samples were extracted to perform laboratory tests for the identification of the principal geotechnical parameters. The goal was to obtain a reliable geological/geotechnical model in front of the Trieste Marine Terminal -from the seabed to the bedrock. Below the seafloor, a sequence of about 20-30 m thickness, containing Plio-Quaternary soft sediments, overlies the flysch, which locally presents alteration with rocks of reduced quality. The geophysicalgeotechnical integrated approach allowed us to identify and map the top of the bedrock and provided valuable information for planning the pier extension project.

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Seismik

Clauser¹

2017

Grundlagen Der Angewandten Geophysik - Seismik, Gravimetrie

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Estimating quality factor and mean grain size of sediments from high-resolution marine seismic data

Cited by 70 publications

References 32 publications

Pre-stack full waveform inversion of ultra-high-frequency marine seismic reflection data

Pre-stack full waveform inversion of ultra-high-frequency marine seismic reflection data

Near‐shore geophysical and geotechnical investigations in support of the Trieste Marine Terminal extension

Seismik

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