Spatiotemporal Detection and Uncertainty Visualization of Atmospheric Blocking Events

TL;DR

This paper introduces a novel framework for detecting atmospheric blocking events and visualizing their uncertainties, aiding climate analysis and weather prediction by providing detailed spatiotemporal insights.

Contribution

It presents a geometry-based detection method combined with uncertainty-aware visual summaries, applicable to climate models and reanalysis data, enhancing understanding of blocking events.

Findings

Effective detection of blocking events in climate data

Uncertainty visualization reveals variability and occurrence patterns

Case study demonstrates framework's utility in analyzing the 2003 European heatwave

Abstract

Atmospheric blocking events are quasi-stationary high-pressure systems that disrupt the typical paths of polar and subtropical air currents, often producing prolonged extreme weather events such as summer heat waves or winter cold spells. Despite their critical role in shaping mid-latitude weather, accurately modeling and analyzing blocking events in long meteorological records remains a significant challenge. To address this challenge, we present an uncertainty visualization framework for detecting and characterizing atmospheric blocking events. First, we introduce a geometry-based detection and tracking method, evaluated on both pre-industrial climate model simulations (UKESM) and reanalysis data (ERA5), which represent historical Earth observations assimilated from satellite and station measurements onto regular numerical grids using weather models. Second, we propose a suite of uncertainty-aware summaries: contour boxplots that capture representative boundaries and their variability, frequency heatmaps that encode occurrences, and 3D temporal stacks that situate these patterns in time. Third, we demonstrate our framework in a case study of the 2003 European heatwave, mapping the spatiotemporal occurrences of blocking events using these summaries. Collectively, these uncertainty visualizations reveal where blocking events are most likely to occur and how their spatial footprints evolve over time. We envision our framework as a valuable tool for climate scientists and meteorologists: by analyzing how blocking frequency, duration, and intensity vary across regions and climate scenarios, it supports both the study of historical blocking events and the assessment of scenario-dependent climate risks associated with changes in extreme weather linked to blocking.