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Keele University has a forty year history in the theory, development and application of microseismic (small-magnitude `earthquakes') monitoring and characterisation methods for the investigation of geotechnical, geological and geo-environmental problems, which continues to form a key aspect of its environmental and sustainability agenda, one of Keele's overarching strategic priorities.
Since 1993, Professors Young & Styles' research at Keele (the Applied and Environmental Geophysics Group) has led to new international standards in the monitoring of ground deformation and fracturing associated with underground mining (coal, salt, gypsum), coal-bed methane extraction, high-level nuclear waste disposal and, most recently, the emission of low-frequency vibrational noise from wind turbines and the exploitation of shale gas hydrocarbon reserves.
Keele's research has been instrumental in developing new hardware, software, data acquisition, processing and visualisation technologies that are now considered de facto across the international microseismic monitoring community (both industrial and academic). Keele's research work has contributed to the significant development of new, UK on-shore gas reserves and the de-regulating of Ministry of Defence (MOD) land for long-term renewable energy development.
Keele University has a forty year history in the theory, development and application of microseismic (small-magnitude `earthquakes') monitoring and characterisation methods for the investigation of geotechnical and geo-environmental problems, which continues to form a key aspect of its environmental and sustainability agenda, one of Keele's overarching strategic priorities.
Since 1993, Professors Young & Styles' research at Keele, within the EPSAM Environmental Engineering Group, has led to new international standards in the monitoring of ground deformation and fracturing associated with underground mining (coal, salt, gypsum), coal-bed methane extraction, high-level nuclear waste disposal and, most recently, the emission of low-frequency vibrational noise from wind turbines and the exploitation of shale gas hydrocarbon reserves.
The development of a new compositional tool for electroacoustic music (using technology to explore, create and perform sounds not limited to traditional instrumental sources) based on visual shapes has generated new ways of thinking that influence creative practice, and has inspired and supported new forms of artistic expression. New musical outputs composed by Dr Manuella Blackburn, generated from using the tool, have enriched the lives, imaginations and sensibilities of individuals and groups, locally and internationally. Parallel to this, the tool has been implemented in a number of educational situations (including workshops and textbooks) ranging from school-aged learners (11-18) to university undergraduate students, beyond Liverpool Hope University as the submitting HEI.