Abstract
Abstract. The Canary Islands are an active volcanic region densely populated and visited by several millions of tourists every year. Nearly twenty eruptions have been reported through written chronicles in the last 600 yr, suggesting that the probability of a new eruption in the near future is far from zero. This shows the importance of assessing and monitoring the volcanic hazard of the region in order to reduce and manage its potential volcanic risk, and ultimately contribute to the design of appropriate preparedness plans. Hence, the probabilistic analysis of the volcanic eruption time series for the Canary Islands is an essential step for the assessment of volcanic hazard and risk in the area. Such a series describes complex processes involving different types of eruptions over different time scales. Here we propose a statistical method for calculating the probabilities of future eruptions which is most appropriate given the nature of the documented historical eruptive data. We first characterize the eruptions by their magnitudes, and then carry out a preliminary analysis of the data to establish the requirements for the statistical method. Past studies in eruptive time series used conventional statistics and treated the series as an homogeneous process. In this paper, we will use a method that accounts for the time-dependence of the series and includes rare or extreme events, in the form of few data of large eruptions, since these data require special methods of analysis. Hence, we will use a statistical method from extreme value theory. In particular, we will apply a non-homogeneous Poisson process to the historical eruptive data of the Canary Islands to estimate the probability of having at least one volcanic event of a magnitude greater than one in the upcoming years. This is done in three steps: First, we analyze the historical eruptive series to assess independence and homogeneity of the process. Second, we perform a Weibull analysis of the distribution of repose time between successive eruptions. Third, we analyze the non-homogeneous Poisson process with a generalized Pareto distribution as the intensity function.
Highlights
The Canary Islands are one of the major oceanic island groups of the world and have a long magmatic history, which began at the bottom of the ocean more than 40 million years ago (Arana and Ortiz, 1991)
Volcanic Eruptions dataset used in the study for the volcanic hazard assessment of the Canary Islands
To face this problem of working with small datasets, and to be able to obtain a mathematical quantification of the volcanic hazard as accurate as possible, we look for methods that allow us to work with databases which are small and sometimes incomplete (Coles, 2001; Davison and Smith, 1990; Beguerıa, 2005)
Summary
The Canary Islands are one of the major oceanic island groups of the world and have a long magmatic history, which began at the bottom of the ocean more than 40 million years ago (Arana and Ortiz, 1991). Due to the limitations inherent in the available data, including its short sample time and incomplete reporting of small and intermediate magnitudes as well as uncertainties in the age, intensity and magnitude of the eruptions, we will use a method for the best estimate of the volcanic hazard based on a NonHomogeneous Poisson process with a Generalized Pareto Distribution (GPD) as intensity function (NHGPPP) (Coles, 2001; Mendoza-Rosas and De la Cruz-Reyna, 2008, 2010). We analyze the nonhomogeneous Poisson process with a generalized Pareto distribution as intensity function
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