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The Delayed Island Mass Effect: How Islands can Remotely Trigger Blooms in the Oligotrophic Ocean
Author(s) -
Messié Monique,
Petrenko Anne,
Doglioli Andrea M.,
Aldebert Clément,
Martinez Elodie,
Koenig Guillaume,
Bonnet Sophie,
Moutin Thierry
Publication year - 2020
Publication title -
geophysical research letters
Language(s) - English
Resource type - Journals
SCImago Journal Rank - 2.007
H-Index - 273
eISSN - 1944-8007
pISSN - 0094-8276
DOI - 10.1029/2019gl085282
Subject(s) - bloom , phytoplankton , oceanography , ocean gyre , plankton , environmental science , algal bloom , limiting , productivity , water mass , nutrient , nitrate , biomass (ecology) , chlorophyll a , ecology , subtropics , biology , geology , botany , mechanical engineering , macroeconomics , engineering , economics
Abstract In oligotrophic gyres of the tropical ocean, islands can enhance phytoplankton biomass and create hotspots of productivity and biodiversity. This “island mass effect” (IME) is typically identified by increased chlorophyll concentrations next to an island. Here we use a simple plankton model in a Lagrangian framework to represent an unexplained open ocean bloom, demonstrating how islands could have triggered it remotely. This new type of IME, termed “delayed IME,” occurs when nitrate is limiting, N:P ratios are low, and excess phosphate and iron remain in water masses after an initial bloom associated with a “classical” IME. Nitrogen fixers then slowly utilize leftover phosphate and iron while water masses get advected away, resulting in a bloom decoupled in time (several weeks) and space (hundreds of kilometers) from island‐driven nutrient supply. This study suggests that the fertilizing effect of islands on phytoplankton may have been largely underestimated.