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(Referência obtida automaticamente do Web of Science, por meio da informação sobre o financiamento pela FAPESP e o número do processo correspondente, incluída na publicação pelos autores.)

Basin stability and limit cycles in a conceptual model for climate tipping cascades

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Autor(es):
Wunderling, Nico [1, 2, 3] ; Gelbrecht, Maximilian [1, 4] ; Winkelmann, Ricarda [2, 3] ; Kurths, Jurgen [1, 4, 5] ; Donges, Jonathan F. [6, 3]
Número total de Autores: 5
Afiliação do(s) autor(es):
[1] Humboldt Univ, Dept Phys, D-12489 Berlin - Germany
[2] Univ Potsdam, Inst Phys & Astron, D-14476 Potsdam - Germany
[3] Leibniz Assoc, Potsdam Inst Climate Impact Res PIK, Earth Syst Anal, D-14473 Potsdam - Germany
[4] Leibniz Assoc, Potsdam Inst Climate Impact Res PIK, Complex Sci, D-14473 Potsdam - Germany
[5] Lobachevsky State Univ Nizhny Novgorod, Nizhnii Novgorod - Russia
[6] Stockholm Univ, Stockholm Resilience Ctr, SE-10691 Stockholm - Sweden
Número total de Afiliações: 6
Tipo de documento: Artigo Científico
Fonte: NEW JOURNAL OF PHYSICS; v. 22, n. 12 DEC 2020.
Citações Web of Science: 0
Resumo

Tipping elements in the climate system are large-scale subregions of the Earth that might possess threshold behavior under global warming with large potential impacts on human societies. Here, we study a subset of five tipping elements and their interactions in a conceptual and easily extendable framework: the Greenland Ice Sheets (GIS) and West Antarctic Ice Sheets, the Atlantic meridional overturning circulation (AMOC), the El-Nino Southern Oscillation and the Amazon rainforest. In this nonlinear and multistable system, we perform a basin stability analysis to detect its stable states and their associated Earth system resilience. By combining these two methodologies with a large-scale Monte Carlo approach, we are able to propagate the many uncertainties associated with the critical temperature thresholds and the interaction strengths of the tipping elements. Using this approach, we perform a system-wide and comprehensive robustness analysis with more than 3.5 billion ensemble members. Further, we investigate dynamic regimes where some of the states lose stability and oscillations appear using a newly developed basin bifurcation analysis methodology. Our results reveal that the state of four or five tipped elements has the largest basin volume for large levels of global warming beyond 4 degrees C above pre-industrial climate conditions, representing a highly undesired state where a majority of the tipping elements reside in the transitioned regime. For lower levels of warming, states including disintegrated ice sheets on west Antarctica and Greenland have higher basin volume than other state configurations. Therefore in our model, we find that the large ice sheets are of particular importance for Earth system resilience. We also detect the emergence of limit cycles for 0.6% of all ensemble members at rare parameter combinations. Such limit cycle oscillations mainly occur between the GIS and AMOC (86%), due to their negative feedback coupling. These limit cycles point to possibly dangerous internal modes of variability in the climate system that could have played a role in paleoclimatic dynamics such as those unfolding during the Pleistocene ice age cycles. (AU)

Processo FAPESP: 15/50122-0 - Fenômenos dinâmicos em redes complexas: fundamentos e aplicações
Beneficiário:Elbert Einstein Nehrer Macau
Modalidade de apoio: Auxílio à Pesquisa - Temático