Events & Courses

A geological hazard (geohazard) is the consequence of an adverse combination of geological processes and ground conditions, sometimes precipitated by anthropogenic activity. The term implies that the event is unexpected and likely to cause significant loss or harm. To understand geohazards and mitigate their effects, expertise is required in the key areas of engineering geology, hydrogeology, geotechnical engineering, risk management, communication and planning, supported by appropriate specialist knowledge of subjects such as seismology and volcanology. There is a temptation for geoscientists involved in geohazards to get too focused on the ‘science’ and lose sight of the purpose of the work, which is to facilitate the effective management and mitigation of the consequences of geohazards within society.

The study and assessment of geohazards into the wider social context, helping the engineering geologist to better communicate the issues concerning geohazards in the UK to the client and the wider public.

Course overview

This course is ideal for geoscientists who are geoengineers, geotechnical experts or those who work in contaminated land. It is also useful for those who are in parallel sectors.

Each module is structured to give a presentation which sets the scene for the specific hazard, followed by discussion to develop understanding of the monitoring and the various elements which contribute to possible mitigation.

Each module is focused on a particular Geohazard.

Course module

Module 5. Coal hazard – mining subsidence plus fault reactivation

From 1750 to the 1970s the UK coal industry was the lifeblood of the Industrial revolution and UK energy, peak extraction taking place in 1912-13. Coal mines varied from single tunnels (adits) driven into hillsides over time to collieries employing 1000s of men with twin shafts to depths of over 3000ft. In South Wales alone there are over 1400 recorded mines. Before 1840, there was no legal requirement to make any maps of mining activities. Due to the large number of tragic accidents, in 1840 a law came into force that coal mines had to maintain an accurate underground map. When mines closed these maps were often discarded, so the law was amended in 1872 that on abandonment all mine plans had to be deposited in a central datastore. With privatisation of British Coal in 1994 all mine plans were transferred to the Coal Authority in Mansfield. Today the detailed paper plans are now available in digital format and can be incorporated into modern GIS.

When coal is extracted underground, the subsequent collapse of the strata can result in surface deformation or subsidence, this can take the form of crown holes or troughs. Often coal mining zones (takes) were naturally bounded by geological faults. Differential subsidence has caused some of these faults to become reactivated, resulting in a linear scarp on the land surface. Old mine shafts that were infilled with wooden rafts can potentially fail many decades later. In operation, mines were either naturally draining or kept dry by pumping. On abandonment over a period of 30 years, the groundwater can rebound. This minewater is often polluted by Iron Pyrites that can result in a red ochre staining polluting of local rivers. Waste from the mining process was usually deposited in tips without any careful engineering. Failure of tip on a steep valley side culminated in the tragedy of the Aberfan disaster in October 1966. After Aberfan many of the tips were reprofiled but with recent heavy rainfall events we have seen a re-occurrence of tip failures in South Wales.

Speaker

Dr Peter Brabham

Peter Brabham was born in the Rhondda Fawr Valley South Wales in a coal mining family, his grandfather was killed in a coal mining accident in 1956. As a child he played on the local abandoned colliery site throwing stones down the open shaft. Peter graduated in 1982 with a degree in Exploration Geophysics from Cardiff University. He then spent four years at Durham University researching into the application of seismic surveying to shallow onshore coal deposits. His time at Durham coincided with the UK miners’ strike of 1984-5. After gaining his PhD he took up a temporary post teaching at Cardiff University and 33 years later he is still there. In 1992 his geophysics research students formed the Terradat geophysical survey company. For the past decade, Peter has been the Director of the highly respected MSc Applied Environmental Geology programme. His expertise in South Wales coal geology is now being utilised by the FLEXIS Energy programme in Wales to investigate the ground heat potential of minewater in the abandoned coal mines.

Registration

Registration will close 24 hours before the session takes place.

Concessionary Rates & Student Registration

We offer students a generous discount, please verify your student status by either registering with your student email address, or upload a photograph of your student identification/ acceptance letter.

The society offers a limited number of concessionary rates for those in financial hardship. Please contact [email protected] (please note you may be required to provide details/evidence to support your application for this rate).

Book the full course series

Book all 15 modules as a package with the Full Course option and enjoy a discount.

Book the full course series plus Special Publication

Book all 15 modules as a package plus Special Publication Geological Hazards in the UK: Their Occurrence, Monitoring and Mitigation by registering for the Full Course option and selecting the book package on the registration form.

We can offer bespoke discounts on group registrations of 5 or more. Please email [email protected] to enquire.

Alternatively, if you book all 15 modules it includes a discount.

Venue

These courses will be held virtually over Zoom between 16.00 GMT and will run until approximately 17.30 GMT depending on audience participation.

Delegates will receive joining instructions the day before they take place.