Probability, Uncertainty and Risk in the Environment
Lead Research Organisation:
University of Reading
Department Name: Meteorology
Abstract
Natural hazards pose serious problems to society and to the global economy. Recent examples in the UK include the cold winters of 2009 and 2010 and the eruptions of the Grimsvotn and Eyjafjallajökull volcanoes with the consequent disruption to air travel. Moving further afield, the first half of 2011 saw major disasters in Australia (flood), New Zealand (earthquake), Japan (earthquake and tsunami) and the US (hurricanes).
It would be nice if scientists could provide precise information to help with the management of such events. This is unrealistic, however, for several reasons: data are usually incomplete (e.g. not available at all required locations) and measured with error; predictions are made using computer models that can at best approximate reality; and our understanding of some phenomena is limited by lack of experience (for example, the historical tsunami record is relatively limited). Therefore, natural hazard scientists must acknowledge the uncertainty in the information they provide, and must communicate this uncertainty effectively to users of the science. However, neither of these tasks is easy. Moreover, scientists do not always understand what users want and need; and users themselves often are uncomfortable with uncertainty.
Despite these problems, modern statistical methods are available for handling uncertainty in complex systems using probability theory. In parallel, social science researchers are interested in understanding how people react to and understand uncertainty. By bringing these two developments together, and linking with scientists from several hazard areas along with a variety of users, we aim (a) to demonstrate a generic framework for handling uncertainty across hazards; and (b) to develop improved tools for communicating uncertain information.
The generic framework considered here has three core components. The first is the treatment of uncertainties arising from our imperfect models and imperfect understanding of any complex system. The second is the combination of information from various sources that are all judged to be relevant: this is particularly important in event management situations where decision-makers must take rapid action based on multiple strands of evidence that might be apparently contradictory. The third is the treatment of uncertainties that are deemed to be "unquantifiable" or too hard to handle:an example from the insurance industry involves how much money to set aside to cover the cost of an event that is known to be possible but for which no historical loss data are available (such as an Atlantic tsunami caused by the collapse of the Cumbre Vieja volcano in La Palma). Five case studies will be used to illustrate the framework: (1) flood risk management in the UK; (2) earthquake hazard in the UK (relevant to the nuclear power industry) and in Italy; (3) tsunami hazard and risk assessment, including the development of methods to improve real-time warning systems; (4) the interpretation of days-ahead weather forecasts (focusing on wind speeds and cold weather); (5) volcanic ash dispersal, again including real-time warning systems.
A final, and critical, component of the proposed research relates to the communication and use of the uncertainty information derived from the three previous components. Working with industrial partners, we will demonstrate how an improved understanding of uncertainty in the hazard itself can be translated through into risk assessments (which focus on the consequence of the hazard, for example the economic loss or damage to infrastructure). We will also carry out research to understand better how people perceive and use risk information. The results will be used to inform the development of novel methods for communicating natural hazard risk information to specialist and non-specialist users; and also (in collaboration with the PURE Network) to produce a handbook of risk communication for natural hazards.
It would be nice if scientists could provide precise information to help with the management of such events. This is unrealistic, however, for several reasons: data are usually incomplete (e.g. not available at all required locations) and measured with error; predictions are made using computer models that can at best approximate reality; and our understanding of some phenomena is limited by lack of experience (for example, the historical tsunami record is relatively limited). Therefore, natural hazard scientists must acknowledge the uncertainty in the information they provide, and must communicate this uncertainty effectively to users of the science. However, neither of these tasks is easy. Moreover, scientists do not always understand what users want and need; and users themselves often are uncomfortable with uncertainty.
Despite these problems, modern statistical methods are available for handling uncertainty in complex systems using probability theory. In parallel, social science researchers are interested in understanding how people react to and understand uncertainty. By bringing these two developments together, and linking with scientists from several hazard areas along with a variety of users, we aim (a) to demonstrate a generic framework for handling uncertainty across hazards; and (b) to develop improved tools for communicating uncertain information.
The generic framework considered here has three core components. The first is the treatment of uncertainties arising from our imperfect models and imperfect understanding of any complex system. The second is the combination of information from various sources that are all judged to be relevant: this is particularly important in event management situations where decision-makers must take rapid action based on multiple strands of evidence that might be apparently contradictory. The third is the treatment of uncertainties that are deemed to be "unquantifiable" or too hard to handle:an example from the insurance industry involves how much money to set aside to cover the cost of an event that is known to be possible but for which no historical loss data are available (such as an Atlantic tsunami caused by the collapse of the Cumbre Vieja volcano in La Palma). Five case studies will be used to illustrate the framework: (1) flood risk management in the UK; (2) earthquake hazard in the UK (relevant to the nuclear power industry) and in Italy; (3) tsunami hazard and risk assessment, including the development of methods to improve real-time warning systems; (4) the interpretation of days-ahead weather forecasts (focusing on wind speeds and cold weather); (5) volcanic ash dispersal, again including real-time warning systems.
A final, and critical, component of the proposed research relates to the communication and use of the uncertainty information derived from the three previous components. Working with industrial partners, we will demonstrate how an improved understanding of uncertainty in the hazard itself can be translated through into risk assessments (which focus on the consequence of the hazard, for example the economic loss or damage to infrastructure). We will also carry out research to understand better how people perceive and use risk information. The results will be used to inform the development of novel methods for communicating natural hazard risk information to specialist and non-specialist users; and also (in collaboration with the PURE Network) to produce a handbook of risk communication for natural hazards.
Planned Impact
The proposed research will benefit all individuals and organisations with an interest in understanding, responding to and planning for natural hazards and their consequences. Excluding academic beneficiaries, these include:
- Business and industry, in particular the financial (notably insurance), energy, aviation and built environment sectors;
- Organisations such as DEFRA, the Environment Agency and SEPA, with responsibility for natural hazard risk management in the UK and elsewhere;
- Agencies responsible for the provision of risk and hazard management information, such as the UK Meteorological Office (UKMO);
- The general public, including schoolchildren.
For these non-academic beneficiaries, the primary impact of the research will arise from improved communication between the science and user communities, so that the science becomes more relevant to the users and the users are better able to understand the science. The requirements here work both ways. Our engagement with users and industrial partners, and research on communication under Work Package D, aims to foster better understanding of user needs by scientists. Simultaneously however, we will help users to develop a better understanding of what science can and cannot be expected to provide, and to make effective use of uncertain information in decision-making. Apart from the direct engagement with our industrial partners, much of this work will be carried out via dissemination, engagement and training events organised in collaboration with the PURE Network.
Further details of the research impact can be found in our "Pathways to Impact" statement.
- Business and industry, in particular the financial (notably insurance), energy, aviation and built environment sectors;
- Organisations such as DEFRA, the Environment Agency and SEPA, with responsibility for natural hazard risk management in the UK and elsewhere;
- Agencies responsible for the provision of risk and hazard management information, such as the UK Meteorological Office (UKMO);
- The general public, including schoolchildren.
For these non-academic beneficiaries, the primary impact of the research will arise from improved communication between the science and user communities, so that the science becomes more relevant to the users and the users are better able to understand the science. The requirements here work both ways. Our engagement with users and industrial partners, and research on communication under Work Package D, aims to foster better understanding of user needs by scientists. Simultaneously however, we will help users to develop a better understanding of what science can and cannot be expected to provide, and to make effective use of uncertain information in decision-making. Apart from the direct engagement with our industrial partners, much of this work will be carried out via dissemination, engagement and training events organised in collaboration with the PURE Network.
Further details of the research impact can be found in our "Pathways to Impact" statement.
Organisations
Publications
Charlton-Perez A
(2019)
Storm naming and forecast communication: A case study of Storm Doris
in Meteorological Applications
Dacre H
(2016)
How accurate are volcanic ash simulations of the 2010 Eyjafjallajökull eruption?
in Journal of Geophysical Research: Atmospheres
Dacre H
(2015)
Volcanic ash layer depth: Processes and mechanisms
in Geophysical Research Letters
Dacre H
(2018)
Characterizing the Atmospheric Conditions Leading to Large Error Growth in Volcanic Ash Cloud Forecasts
in Journal of Applied Meteorology and Climatology
Ferraro AJ
(2014)
A risk-based framework for assessing the effectiveness of stratospheric aerosol geoengineering.
in PloS one
Lickiss M
(2017)
Developing a quick guide on presenting data and uncertainty
in Weather
Lynch K
(2014)
Verification of European Subseasonal Wind Speed Forecasts
in Monthly Weather Review
McCloy R
(2017)
Visualizing Volcanic Ash Forecasts: Scientist and Stakeholder Decisions Using Different Graphical Representations and Conflicting Forecasts
in Weather, Climate, and Society
Mulder K
(2019)
Designing environmental uncertainty information for experts and non-experts: Does data presentation affect users' decisions and interpretations?
in Meteorological Applications