Landslides and floods are globally occurring natural hazards that pose a significant threat to human life and sustainable development. The most severe losses due to landslides occur in the less economically developed countries of Asia and South America, particularly in those with mountainous topography, earthquakes and monsoonal climates. Landslides and rockfalls in these regions often detach fractured bedrock and deliver large boulders downslope that block roads, destroy buildings and kill people. On entering the river channel network, boulders may be bulldozed by large floods and block hydropower infrastructure, jeopardizing electricity supply and the economy. Thus, boulders may cause a cascade of hazards. This project addresses specific landslide and flood risk management problems brought to our attention by stakeholders impacted by boulders in the Upper Bhote Koshi catchment in Nepal, one of the most landslide and flood-prone countries in the world. This project also addresses a lack of data and scientific understanding of (i) boulder production on hillslopes (e.g. by landslides), (ii) boulder transport in floods. In this two year project, an inter-disciplinary team of researchers will work closely with project partners to (1) map boulders and investigate the controls on boulder production on hillslopes by landslides and rockfalls, (2) develop a new real-time GPS boulder tracking system with which to improve understanding of boulder movement in floods and monitor hazardous boulders (3) engage with stakeholders to incorporate findings into disaster management plans and ultimately to increase resilience to landslide and flood hazards. The project will focus on the Upper Bhote Koshi (UBK) catchment to the north east of Kathmandu, Nepal, and has been designed with specific end users in mind in the UBK that are dealing with boulder hazards related to landslide and floods. This area is particularly vulnerable to boulder hazards as it is the main road link between Nepal and China and contains several major hydroelectric power plants including the Upper Bhote Koshi Hydroelectric Power plant (UBKHEP). The catchment encapsulates the multitude of natural hazards faced by Nepal. In 2015 the catchment was shaken by the Gorkha earthquake generating some of the highest densities of landsliding anywhere in Nepal. In July 2016, a complex monsoon flash flood entrained extremely large boulders (>8 m) some of which became jammed in the sluice gates of the UBKHEP culminating in more than $110 m damage to the power station. The power station remains closed resulting in lost revenue and compromising Nepal's energy supply. As the power company rebuilds and a further hydroelectric power station is built just downstream, it will be vital to properly account for future boulder hazards in landslide and floods. The project brings together an interdisciplinary team of researchers based in the UK, Germany and Nepal with several project partners that have helped to define the problems that this project will address. The boulder hazard map and boulder tracking system developed in this research will help make the Bhote Koshi Power Company and wider hydropower industry more resilient to landslide and flood hazards. The research will also benefit organizations managing transport infrastructure and communities living on steep, landslide prone hillslopes in the Bhote Koshi. We will hold two project workshops bringing together project partners and relevant stakeholders from industry, local communities and government institutions with the help of Practical Action Consulting Nepal, to research boulder hazard perception and enhance uptake of this research into risk management practice at local and national governance level and ultimately to aid development in Nepal and South Asia.

Landslides and floods are globally occurring natural hazards that pose a significant threat to human life and sustainable development. The most severe losses due to landslides occur in the less economically developed countries of Asia and South America, particularly in those with mountainous topography, earthquakes and monsoonal climates. Landslides and rockfalls in these regions often detach fractured bedrock and deliver large boulders downslope that block roads, destroy buildings and kill people. On entering the river channel network, boulders may be bulldozed by large floods and block hydropower infrastructure, jeopardizing electricity supply and the economy. Thus, boulders may cause a cascade of hazards. This project addresses specific landslide and flood risk management problems brought to our attention by stakeholders impacted by boulders in the Upper Bhote Koshi catchment in Nepal, one of the most landslide and flood-prone countries in the world. This project also addresses a lack of data and scientific understanding of (i) boulder production on hillslopes (e.g. by landslides), (ii) boulder transport in floods. In this two year project, an inter-disciplinary team of researchers will work closely with project partners to (1) map boulders and investigate the controls on boulder production on hillslopes by landslides and rockfalls, (2) develop a new real-time GPS boulder tracking system with which to improve understanding of boulder movement in floods and monitor hazardous boulders (3) engage with stakeholders to incorporate findings into disaster management plans and ultimately to increase resilience to landslide and flood hazards. The project will focus on the Upper Bhote Koshi (UBK) catchment to the north east of Kathmandu, Nepal, and has been designed with specific end users in mind in the UBK that are dealing with boulder hazards related to landslide and floods. This area is particularly vulnerable to boulder hazards as it is the main road link between Nepal and China and contains several major hydroelectric power plants including the Upper Bhote Koshi Hydroelectric Power plant (UBKHEP). The catchment encapsulates the multitude of natural hazards faced by Nepal. In 2015 the catchment was shaken by the Gorkha earthquake generating some of the highest densities of landsliding anywhere in Nepal. In July 2016, a complex monsoon flash flood entrained extremely large boulders (>8 m) some of which became jammed in the sluice gates of the UBKHEP culminating in more than $110 m damage to the power station. The power station remains closed resulting in lost revenue and compromising Nepal's energy supply. As the power company rebuilds and a further hydroelectric power station is built just downstream, it will be vital to properly account for future boulder hazards in landslide and floods. The project brings together an interdisciplinary team of researchers based in the UK, Germany and Nepal with several project partners that have helped to define the problems that this project will address. The boulder hazard map and boulder tracking system developed in this research will help make the Bhote Koshi Power Company and wider hydropower industry more resilient to landslide and flood hazards. The research will also benefit organizations managing transport infrastructure and communities living on steep, landslide prone hillslopes in the Bhote Koshi. We will hold two project workshops bringing together project partners and relevant stakeholders from industry, local communities and government institutions with the help of Practical Action Consulting Nepal, to research boulder hazard perception and enhance uptake of this research into risk management practice at local and national governance level and ultimately to aid development in Nepal and South Asia.

Floods and landslides affect the UK every year, both inland and along the coast, causing disruption, occasional fatalities and severe economic loss. An increase in storminess under climate change and population pressure are resulting in an increase in landslide and flood hazards in the UK and globally and threatening the defences put in place to manage these hazards. Monitoring of unstable hillslopes and flood-prone rivers as well as defences designed to manage these is increasingly vital. Landslides and floods are both triggered by heavy rainfall, often occur at the same time, and may interact to generate a chain reaction of knock-on hazardous effects. SENSUM proposes a new integrated way to tackle these 'hydrogeological' hazards, taking advantage of advances in Wireless Sensor Network (WSN) and Internet of Things (IoT) technologies, microelectronics and machine learning. Those exciting new tools will be used to monitor the stability of defences, provide warnings of hazard events, and improve mathematical models and visualisation of hazardous phenomena. Landslides and floods have traditionally been monitored using a combination of satellite-based remote-sensing techniques and wired ground-based instruments to measure factors that control the related hazard, such as river flow level, displacement and soil moisture. Wireless sensor networks (WSNs) show great potential for monitoring and early warning of these hazards. Their main advantage is their use of easily deployable, low-power sensors enabling continuous, long-term, low-cost monitoring of the environment. For landslides and floods, which occur infrequently and unpredictably, this is an important technological advance. SENSUM proposes to develop innovative smart tracking devices, embedded in boulders and woody debris on hillslopes and in rivers to give real-time warning of movement related to landslide and flood processes. Collaborating closely with external partners, the team of experts in the SENSUM project will develop and test the tracking devices both in dedicated laboratory experiments and in the field, with the deployment of trial networks of smart boulders and woody debris in different localities in the UK and abroad. The large set of data obtained from sites and experiments will be used to improve mathematical models, to develop innovative early warning systems and in 3D digital visualisations. This integrated approach will enable us to establish a comprehensive understanding of landslide and flood processes which will significantly reduce risk to society. The SENSUM team is a diverse, interdisciplinary and multinational team made up of a range of environmental scientists and engineers, computer scientists and science communication specialists from three leading UK universities: University of Exeter, University of East Anglia and University of Plymouth and will involve several project partners including the Environment Agency, Forest England, Natural England and AECOM. It will work closely with these project partners to design an effective digital environment for monitoring and managing landslide and flood hazards in the UK, and to target applied risk management challenges. For example, in the UK, the Environment Agency is tasked with giving a 2-hour warning to the population affected by floods. However, these warnings are lacking in the upland areas of the UK's landscape due to a lack of instruments to monitor river flow. The smart tracking devices embedded within boulder and woody debris in landslides and river channels proposed by SENSUM will help address that limitation, and therefore will significantly improve early warning of movement and consequently the assessment of potential high-risk natural events. The team will also engage stakeholders and the general public through the creation of compelling visualizations of landslide and flood hazards and through project workshops and outreach activities.