BOPS Publications

• Verdon, J.P., and L. Eisner, 2024. An empirically constrained forecasting strategy for induced earthquake magnitudes using extreme value theory: Seismological Research Letters, in press. DOI: 10.1785/0220240061
• Lapins, S., A. Butcher, J-M. Kendall, T.S. Hudson, A.L. Stork, M.J. Werner, J. Gunning, A.M. Brisbourne. DAS-N2N: machine learning distributed acoustic sensing (DAS) signal denoising without clean data: Geophysical Journal International 236, 1026-1041. DOI: 10.1093/gji/ggad460
• Hudson, T.S., T. Kettlety, J.-M. Kendall, T. O’Toole, A. Jupe, R.K. Shail, A. Grand, 2024. Seismic node arrays for enhanced understanding and monitoring of geothermal systems: The Seismic Record 4, 161-171. DOI: 10.1785/0320240019
• Kettlety, T., E. Martuganova, D. Kühn, J. Schweitzer, C. Weemstra, B. Baptie, T. Dahl-Jensen, A. Jerkins, P.H. Voss, J.-M. Kendall, E. Skurtveit, 2024. A unified catalogue for the North Sea to de-risk European CCS operations: First Break 42, 31-36. DOI: 10.3997/1365-2397.fb2024036
• Rodriguez-Pradilla, G., and J.P. Verdon, 2024. Quantifying the variability in fault density across the UK Bowland Shale, with implications for induced seismicity hazard: Geomechanics for Energy and the Environment 38, 100534. DOI: 10.1016/j.gete.2024.100534
• Verdon, J.P., B. Pullen, G. Rodriguez-Pradilla, 2024. Growth and stabilisation of induced seismicity rates during long-term, low pressure fluid injection: Philosophical Transactions of the Royal Society A 382, 20230183. DOI: 10.1098/rsta.2023.0183
• Watkins, T.J.M., J.P. Verdon, G. Rodriguez-Pradilla, 2023. The temporal evolution of induced seismicity sequences generated by long-term, low pressure fluid injection: Journal of Seismology 27, 243-259. DOI 10.1007/s10950-023-10141-z
• Igonin, N., J.P. Verdon, D.W. Eaton, 2022. Seismic anisotropy reveals stress changes around a fault as it is activated by hydraulic fracturing: Seismological Research Letters 93, 1737-1752. DOI: 10.1785/0220210282
• Verdon, J.P., and G. Rodriguez-Pradilla, 2023. Assessing the variability in hydraulic fracturing-induced seismicity occurrence between North American shale plays: Tectonophysics 859, 229898. DOI: 10.1016/j.tecto.2023.229898
• Kettlety T., J.P. Verdon, A. Butcher, M. Hampson, L. Craddock, 2021. High‐resolution imaging of the M_L 2.9 August 2019 earthquake in Lancashire, United Kingdom, induced by hydraulic fracturing during Preston New Road PNR‐2 operations: Seismological Research Letters 92, 151-169. DOI 10.1785/0220200187
• Verdon J.P. and J.J. Bommer, 2021. Green, yellow, red, or out of the blue? An assessment of Traffic Light Schemes to mitigate the impact of hydraulic fracturing-induced seismicity: Journal of Seismology 25, 301-326. DOI: 10.1007/s10950-020-09966-9
• Igonin, N., J.P. Verdon, J-M. Kendall, D.W. Eaton, 2021. Large-scale fracture systems are permeable pathways for fault activation during hydraulic fracturing: Journal of Geophysical Research 126, e2020JB020311. DOI: 10.1029/2020JB020311
• Verdon J.P., S.A. Horne, A. Clarke, A.L. Stork, A.F. Baird, J-M. Kendall, 2020. Microseismic monitoring using a fibre-optic Distributed Acoustic Sensor (DAS) array: Geophysics 85, 1MJ-Z13. DOI: 10.1190/geo2019-0752.1
• Stork A.L., A.F. Baird, S.A. Horne, G. Naldrett, S. Lapins, J-M. Kendall, J. Wookey, J.P. Verdon, A. Clarke, A. Williams, 2020. Application of machine learning to microseismic event detection in Distributed Acoustic Sensing (DAS) data: Geophysics 85, KS149-KS160. DOI: 10.1190/geo2019-0774.1
• Baird A.F., A.L. Stork, S.A. Horne, G. Naldrett, J-M. Kendall, J. Wookey, J.P. Verdon, A. Clarke, 2020. Characteristics of microseismic data recorded by Distributed Acoustic Sensing (DAS) systems in anisotropic media: Geophysics 85, KS139-KS147. DOI: 10.1190/geo2019-0776.1
• Clarke H., J.P. Verdon, T. Kettlety, A.F. Baird, J-M. Kendall, 2019. Real time imaging, forecasting and management of human-induced seismicity at Preston New Road, Lancashire, England: Seismological Research Letters 90, 1902-1915. DOI: 10.1785/0220190110