Impacts from cascading multi-hazards using hypergraphs: a case study from the 2015 Gorkha earthquake in Nepal
(2024)
Journal Article
Dunant, A., Robinson, T. R., Densmore, A. L., Rosser, N. J., Rajbhandari, R. M., Kincey, M., Li, S., Awasthi, P. R., Van Wyk de Vries, M., Guragain, R., Harvey, E., & Dadson, S. (in press). Impacts from cascading multi-hazards using hypergraphs: a case study from the 2015 Gorkha earthquake in Nepal. Natural Hazards and Earth System Sciences, https://doi.org/10.5194/egusphere-2024-1374
Mark Kincey's Outputs (23)
Modelling post-earthquake cascading hazards: Changing patterns of landslide runout following the 2015 Gorkha earthquake, Nepal (2022)
Journal Article
Kincey, M., Rosser, N., Densmore, A., Robinson, T., Shrestha, R., Pujara, D., Horton, P., Swirad, S., Oven, K., & Arrell, K. (2023). Modelling post-earthquake cascading hazards: Changing patterns of landslide runout following the 2015 Gorkha earthquake, Nepal. Earth Surface Processes and Landforms, 48(3), 537-554. https://doi.org/10.1002/esp.5501Coseismic landslides represent the first stage of a broader cascading sequence of geohazards associated with high-magnitude continental earthquakes, with the subsequent remobilization of coseismic landslide debris posing a long-term post-seismic lega... Read More about Modelling post-earthquake cascading hazards: Changing patterns of landslide runout following the 2015 Gorkha earthquake, Nepal.
Metals, mines and moorland: the changing lead mining landscapes of the North Pennines, UK, 1700-1948 (2022)
Journal Article
Kincey, M., Gerrard, C., & Warburton, J. (2022). Metals, mines and moorland: the changing lead mining landscapes of the North Pennines, UK, 1700-1948. Post-Medieval Archaeology, 56(1), 1-27. https://doi.org/10.1080/00794236.2022.2058221Intensive metal mining considerably altered many British upland landscapes between the 18th and 20th centuries, modifying both subterranean and surface environments and fundamentally changing the character of local settlements, infrastructure and soc... Read More about Metals, mines and moorland: the changing lead mining landscapes of the North Pennines, UK, 1700-1948.
Controls on post-seismic landslide behaviour in brittle rocks (2021)
Journal Article
Brain, M., Moya, S., Kincey, M., Tunstall, N., Petley, D., & Sepúlveda, S. (2021). Controls on post-seismic landslide behaviour in brittle rocks. Journal of Geophysical Research: Earth Surface, 126(9), Article e2021JF006242. https://doi.org/10.1029/2021jf006242Earthquakes trigger widespread landsliding in tectonically-active landscapes. The effects of strong ground shaking on hillslope stability persist into the post-seismic stage; rates of landsliding remain elevated in the years following an earthquake.... Read More about Controls on post-seismic landslide behaviour in brittle rocks.
Changing Significance of Landslide Hazard and Risk After The 2015 Mw 7.8 Gorkha, Nepal Earthquake (2021)
Journal Article
Rosser, N., Kincey, M., Oven, K., Densmore, A., Robinson, T., Pujara, D., Shrestha, R., Smutny, J., Gurung, K., Lama, S., & Dhital, M. (2021). Changing Significance of Landslide Hazard and Risk After The 2015 Mw 7.8 Gorkha, Nepal Earthquake. Progress in disaster science, 10, Article 100159. https://doi.org/10.1016/j.pdisas.2021.100159The 2015 Mw 7.8 Gorkha, Nepal Earthquake triggered in excess of 20,000 landslides across 14 districts of Central and Western Nepal. Whilst the instantaneous impact of these landslides was significant, the ongoing effect of the earthquake on changing... Read More about Changing Significance of Landslide Hazard and Risk After The 2015 Mw 7.8 Gorkha, Nepal Earthquake.
Evolution of coseismic and post‐seismic landsliding after the 2015 Mw 7.8 Gorkha earthquake, Nepal (2021)
Journal Article
Kincey, M. E., Rosser, N. J., Robinson, T. R., Densmore, A. L., Shrestha, R., Pujara, D. S., Oven, K. J., Williams, J. G., & Swirad, Z. M. (2021). Evolution of coseismic and post‐seismic landsliding after the 2015 Mw 7.8 Gorkha earthquake, Nepal. Journal of Geophysical Research: Earth Surface, 126(3), Article e2020JF005803. https://doi.org/10.1029/2020jf005803Coseismic landslides are a major hazard associated with large earthquakes in mountainous regions. Despite growing evidence for their widespread impacts and persistence, current understanding of the evolution of landsliding over time after large earth... Read More about Evolution of coseismic and post‐seismic landsliding after the 2015 Mw 7.8 Gorkha earthquake, Nepal.
Contaminated sediment flux from eroding abandoned historical metal mines: Spatial and temporal variability in geomorphological drivers (2018)
Journal Article
Kincey, M., Warburton, J., & Brewer, P. (2018). Contaminated sediment flux from eroding abandoned historical metal mines: Spatial and temporal variability in geomorphological drivers. Geomorphology, 319, 199-215. https://doi.org/10.1016/j.geomorph.2018.07.026Abandoned historical metal mines represent significant long-term sediment source locations contributing highly contaminated anthropogenic legacy sediments to river systems. Despite this, our understanding of spatial and temporal variability in the ra... Read More about Contaminated sediment flux from eroding abandoned historical metal mines: Spatial and temporal variability in geomorphological drivers.
Satellite-based emergency mapping using optical imagery: experience and reflections from the 2015 Nepal earthquakes (2018)
Journal Article
Williams, J., Rosser, N., Kincey, M., Benjamin, J., Oven, K., Densmore, A., …Dijkstra, T. (2018). Satellite-based emergency mapping using optical imagery: experience and reflections from the 2015 Nepal earthquakes. Natural Hazards and Earth System Sciences, 18, 185-205. https://doi.org/10.5194/nhess-18-185-2018Landslides triggered by large earthquakes in mountainous regions contribute significantly to overall earthquake losses and pose a major secondary hazard that can persist for months or years. While scientific investigations of coseismic landsliding ar... Read More about Satellite-based emergency mapping using optical imagery: experience and reflections from the 2015 Nepal earthquakes.
Rapid post-earthquake modelling of coseismic landsliding intensity and distribution for emergency response decision support (2017)
Journal Article
Robinson, T., Rosser, N., Densmore, A., Williams, J., Kincey, M., Benjamin, J., & Bell, H. (2017). Rapid post-earthquake modelling of coseismic landsliding intensity and distribution for emergency response decision support. Natural Hazards and Earth System Sciences, 17(9), 1521-1540. https://doi.org/10.5194/nhess-17-1521-2017Current methods to identify coseismic landslides immediately after an earthquake using optical imagery are too slow to effectively inform emergency response activities. Issues with cloud cover, data collection and processing, and manual landslide ide... Read More about Rapid post-earthquake modelling of coseismic landsliding intensity and distribution for emergency response decision support.
Quantifying erosion of at risk archaeological sites using repeat terrestrial laser scanning (2017)
Journal Article
Kincey, M., Gerrard, C., & Warburton, J. (2017). Quantifying erosion of at risk archaeological sites using repeat terrestrial laser scanning. Journal of Archaeological Science: Reports, 12, 405-424. https://doi.org/10.1016/j.jasrep.2017.02.003Effective heritage management is reliant on an understanding of the range of current and potential future threats facing archaeological sites. Despite this, the processes leading to the loss of in situ archaeological remains are still poorly understo... Read More about Quantifying erosion of at risk archaeological sites using repeat terrestrial laser scanning.
Preserving the Legacy of Historic Metal-Mining Industries in the Light of the Water Framework Directive and Future Environmental Change in mainland Britain: Challenges for the Heritage Community (2015)
Journal Article
Howard, A., Kincey, M., & Carey, C. (2015). Preserving the Legacy of Historic Metal-Mining Industries in the Light of the Water Framework Directive and Future Environmental Change in mainland Britain: Challenges for the Heritage Community. The Historic Environment: Policy & Practice, 6(1), 3-15. https://doi.org/10.1179/1756750514z.00000000061Contemporary global metal mining is a source of environmental pollution, but in Britain it is our historic mining industry that has left a legacy of contamination in the landscape, around both the immediate mine sites as well as within the river vall... Read More about Preserving the Legacy of Historic Metal-Mining Industries in the Light of the Water Framework Directive and Future Environmental Change in mainland Britain: Challenges for the Heritage Community.
Assessing the changing condition of industrial archaeological remains on Alston Moor, UK, using multisensor remote sensing (2014)
Journal Article
Kincey, M., Batty, L., Chapman, H., Gearey, B., Ainsworth, S., & Challis, K. (2014). Assessing the changing condition of industrial archaeological remains on Alston Moor, UK, using multisensor remote sensing. Journal of Archaeological Science, 45, 36-51. https://doi.org/10.1016/j.jas.2014.02.008Upland environments have the potential to preserve relatively undisturbed multi-period archaeological remains due to reduced anthropogenic impacts such as intensive agriculture. However, these environments can also be extremely fragile and susceptibl... Read More about Assessing the changing condition of industrial archaeological remains on Alston Moor, UK, using multisensor remote sensing.
Immersive visualisation of survey and laser scanning: the case for using computer game engines (2013)
Book Chapter
Challis, K., & Kincey, M. (2013). Immersive visualisation of survey and laser scanning: the case for using computer game engines. In R. Opitz, & D. Cowley (Eds.), Interpreting Archaeological Topography: 3D Data, Visualisation and Observation. Oxbow Books
Assessing the preservation potential of temperate, lowland alluvial sediments using airborne lidar intensity (2011)
Journal Article
Challis, K., Carey, C., Kincey, M., & Howard, A. (2011). Assessing the preservation potential of temperate, lowland alluvial sediments using airborne lidar intensity. Journal of Archaeological Science, 38(2), 301-311. https://doi.org/10.1016/j.jas.2010.09.006
Airborne lidar intensity and geoarchaeological prospection in river valley floors (2011)
Journal Article
Challis, K., Carey, C., Kincey, M., & Howard, A. (2011). Airborne lidar intensity and geoarchaeological prospection in river valley floors. Archaeological Prospection, 18(1), https://doi.org/10.1002/arp.398
A Generic Toolkit for the Visualization of Archaeological Features on Airborne LiDAR Elevation Data (2011)
Journal Article
Challis, K., Forlin, P., & Kincey, M. (2011). A Generic Toolkit for the Visualization of Archaeological Features on Airborne LiDAR Elevation Data. Archaeological Prospection, 18(4), https://doi.org/10.1002/arp.421
Monitoring fragile upland landscapes: The application of airborne lidar (2010)
Journal Article
Kincey, M., & Challis, K. (2010). Monitoring fragile upland landscapes: The application of airborne lidar. Journal for Nature Conservation, 18(2), 126-134. https://doi.org/10.1016/j.jnc.2009.06.003
Airborne remote sensing of valley floor geoarchaeology using Daedalus ATM and CASI (2009)
Journal Article
Challis, K., Kincey, M., & Howard, A. (2009). Airborne remote sensing of valley floor geoarchaeology using Daedalus ATM and CASI. Archaeological Prospection, 16(1), 17-33. https://doi.org/10.1002/arp.340
Archaeological resource modelling in temperate river valleys: a case study from the Trent Valley, UK (2008)
Journal Article
Howard, A., Brown, A., Carey, C., Challis, K., Cooper, L., Kincey, M., & Toms, P. (2008). Archaeological resource modelling in temperate river valleys: a case study from the Trent Valley, UK. Antiquity, 82(318), 1040-1054. https://doi.org/10.1017/s0003598x00097763
The impact of climate change on archaeological resources in Britain: a catchment scale assessment (2008)
Journal Article
Howard, A., Challis, K., Holden, J., Kincey, M., & Passmore, D. (2008). The impact of climate change on archaeological resources in Britain: a catchment scale assessment. Climatic Change, 91(3-4), 405-422. https://doi.org/10.1007/s10584-008-9426-9