Downward continuation of marine seismic reflection data: An undervalued tool to improve velocity models

TL;DR

This paper introduces an open-source high-performance computing software for downward continuation of marine seismic data, enhancing subsurface velocity modeling by transforming data to the seafloor for improved interpretation.

Contribution

It provides a user-friendly, open-source HPC tool for downward continuation of 2D marine seismic data, with assessment and analysis features to improve velocity models.

Findings

Effective redatuming of 2D streamer data to seafloor

Enhanced visibility of seismic phases for tomography

Guidelines for data quality assessment after redatuming

Abstract

The purpose of marine seismic experiments is to provide information of the structure and physical properties of the subsurface. The P-wave velocity distribution is the most commonly modelled property, usually by inversion of arrival times or waveform attributes. The most widely used tool to extract refractions as first arrivals from MCS recordings is the so-called downward continuation technique, which is designed for redatuming streamer field data to the seafloor. In this new virtual configuration, the early refractions transform to seismic phases that are becoming visible as first arrivals from nearly zero offset, facilitating its identification and use in travel-time tomography. However, there is limited literature, let alone available codes, to be used with the available MCS data sets. This work presents a user friendly open source HPC software for redatuming 2D streamer field data to the sea bottom for any seafloor relief. The main ingredient is the acoustic wave equation used backward in time, allowing first the redatuming of the receivers, and after, the redatuming of the sources. Assessment tools are provided to evaluate the information available after redatuming for specific data acquisition configurations. Also, we present a step-by-step analysis that defines the most important features that influence the quality of the virtual, redatumed recordings.