Marine Heatwaves Are Not a Dominant Driver of Change in Demersal Fishes

Overview

Journal Nature

Specialty Science

Date 2023 Aug 30

PMID 37648851

Authors

Alexa L Fredston

William W L Cheung

Thomas L Frolicher

Zoe J Kitchel

Aurore A Maureaud

James T Thorson

Arnaud Auber

Bastien Merigot

Juliano Palacios-Abrantes

Maria Lourdes D Palomares

Laurene Pecuchet

Nancy L Shackell

Malin L Pinsky

Affiliations

Soon will be listed here.

Abstract

Marine heatwaves have been linked to negative ecological effects in recent decades. If marine heatwaves regularly induce community reorganization and biomass collapses in fishes, the consequences could be catastrophic for ecosystems, fisheries and human communities. However, the extent to which marine heatwaves have negative impacts on fish biomass or community composition, or even whether their effects can be distinguished from natural and sampling variability, remains unclear. We investigated the effects of 248 sea-bottom heatwaves from 1993 to 2019 on marine fishes by analysing 82,322 hauls (samples) from long-term scientific surveys of continental shelf ecosystems in North America and Europe spanning the subtropics to the Arctic. Here we show that the effects of marine heatwaves on fish biomass were often minimal and could not be distinguished from natural and sampling variability. Furthermore, marine heatwaves were not consistently associated with tropicalization (gain of warm-affiliated species) or deborealization (loss of cold-affiliated species) in these ecosystems. Although steep declines in biomass occasionally occurred after marine heatwaves, these were the exception, not the rule. Against the highly variable backdrop of ocean ecosystems, marine heatwaves have not driven biomass change or community turnover in fish communities that support many of the world's largest and most productive fisheries.

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