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Journal of the Australian Society of Exploration Geophysicists
RESEARCH ARTICLE

Poynting vector-guided imaging condition for imaging fractures using microseismic data

Yeonghwa Jo 1 Soon Jee Seol 1 Hyungwook Choi 2 Joongmoo Byun 1 3
+ Author Affiliations
- Author Affiliations

1 Department of Earth Resources and Environmental Engineering, 222, Wangsimni-ro, Seongdong-gu, Seoul 04763, Korea.

2 SK Innovation, 26, Jong-ro, Jongno-gu, Seoul 03188, Korea.

3 Corresponding author. Email: jbyun@hanyang.ac.kr

Exploration Geophysics 49(6) 856-867 https://doi.org/10.1071/EG18004
Submitted: 4 January 2018  Accepted: 7 January 2018   Published: 5 April 2018
Originally submitted to KSEG 11 September 2017, accepted 19 December 2017  

Abstract

Hydraulic fracturing has been implemented in enhanced geothermal systems and in developing unconventional reservoirs to increase the permeability of earth media. To improve safety during the hydraulic fracturing, a method is proposed for imaging pre-existing fractures adjacent to the hydro-fractured zones based on observed seismic signals during microseismic monitoring using the elastic reverse time migration with source-independent converted phase (ERTM SICP) imaging condition. The ERTM SICP imaging condition is more computationally efficient than the conventional ERTM method, and it can be used to perform migration without information on the locations of source events. It is therefore appropriate for handling microseismic data.

However, because of the difference between P- and S-wave velocities and complex geometry, ERTM SICP imaging condition produces spurious events that can be confused with fractures when applied to reflected waves. Based on the idea that the propagation directions of the P- and S-waves at mode converting points are very similar, whereas those in other regions are commonly different, we modified the imaging condition by adding a weighting function calculated from the Poynting vector of the P- and S-waves. The weighting function has different values depending on the angle between the propagation directions of the P- and S-waves. Based on the tests of the imaging performance of this modified imaging condition, we confirm that our method can successfully suppress the linear spurious events that appear in non-mode-converting regions.

Key words: fracture imaging, microseismic monitoring, Poynting vector, reverse time migration, spurious event.


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