Synchronous marine pelagic regime shifts in the Northern Hemisphere

• Published in: Philosophical transactions of the Royal Society of London. Series B. Biological sciences Vol. 370; no. 1659; pp. 1 - 16
• Main Authors: Beaugrand, G., Conversi, A., Chiba, S., Edwards, M., Fonda-Umani, S., Greene, C., Mantua, N., Otto, S. A., Reid, P. C., Stachura, M. M., Stemmann, L., Sugisaki, H.
• Format: Journal Article
• Language: English
• Published: Royal Society 05.01.2015; The Royal Society; Royal Society, The
• Subjects: Arctic Oscillation; Earth Sciences; Marine; Marine Ecology; Northern Hemisphere Temperature; Oceanography; Pacific Decadal Oscillation; PART II: DRIVERS OF MARINE REGIME SHIFTS; Regime Shift; Sciences of the Universe; Synchronicity
• ISSN: 0962-8436; 1471-2970; 1471-2970
• DOI: 10.1098/rstb.2013.0272

Regime shifts are characterized by sudden, substantial and temporally persistent changes in the state of an ecosystem. They involve major biological modifications and often have important implications for exploited living resources. In this study, we examine whether regime shifts observed in 11 marine systems from two oceans and three regional seas in the Northern Hemisphere (NH) are synchronous, applying the same methodology to all. We primarily infer marine pelagic regime shifts from abrupt shifts in zooplankton assemblages, with the exception of the East Pacific where ecosystem changes are inferred from fish. Our analyses provide evidence for quasi-synchronicity of marine pelagic regime shifts both within and between ocean basins, although these shifts lie embedded within considerable regional variability at both year-to-year and lower-frequency time scales. In particular, a regime shift was detected in the late 1980s in many studied marine regions, although the exact year of the observed shift varied somewhat from one basin to another. Another regime shift was also identified in the mid- to late 1970s but concerned less marine regions. We subsequently analyse the main biological signals in relation to changes in NH temperature and pressure anomalies. The results suggest that the main factor synchronizing regime shifts on large scales is NH temperature; however, changes in atmospheric circulation also appear important. We propose that this quasi-synchronous shift could represent the variably lagged biological response in each ecosystem to a large-scale, NH change of the climatic system, involving both an increase in NH temperature and a strongly positive phase of the Arctic Oscillation. Further investigation is needed to determine the relative roles of changes in temperature and atmospheric pressure patterns and their resultant teleconnections in synchronizing regime shifts at large scales.