<p>Decomposition of bloom-forming organisms often causes coastal hypoxia. To predict hypoxia, the density of a bloom-forming species, its decline rate, and oxygen consumption rate during decomposition should be determined. To determine these parameters, the density of morphologically intact and partially decomposed (PD) cells, and dissolved oxygen (DO) concentrations during a five-day incubation in darkness were measured. Using these data, the decline rate of cell density (k<sub>decline</sub>) and oxygen consumption rate per decomposed cell (OC<sub>decomposed cell</sub>) of seven bloom-forming species, including diatoms <i>Skeletonema dohrnii</i>, <i>Thalassiosira minuscula</i> and <i>Chaetoceros peruvianus</i>, dinoflagellates <i>Margalefidinium polykrikoides</i> and <i>Tripos furca</i>, and nanoflagellates <i>Teleaulax amphioxeia</i> and <i>Heterosigma akashiwo</i> were calculated. Among the species, <i>Te</i>. <i>amphioxeia</i> had the highest k<sub>decline</sub>, 0.66 d<sup>− 1</sup>, and <i>M</i>. <i>polykrikoides</i> had the highest OC<sub>decomposed cell</sub>, 69 pmol O<sub>2</sub> cell<sup>−1</sup>d<sup>− 1</sup>. k<sub>decline</sub> were species-specific and showed no correlation with cell carbon biomass, whereas OC<sub>decomposed cell</sub> showed positive correlation with cell carbon biomass. When DO during decomposition of the species were estimated based on k<sub>decline</sub> value of (1) intact cells only, (2) intact plus PD<sub>0.5</sub> cells, and (3) intact plus PD<sub>1</sub> cells, the estimates using intact plus PD<sub>0.5</sub> cells for dinoflagellates and intact plus PD<sub>1</sub> cells for the others were closest to the measured DO. Furthermore, the Q<sub>10</sub> coefficient calculated from the k<sub>decline</sub> for <i>S</i>. <i>dohrnii</i> determined at 15 and 25&#xa0;°C was 3.1. The present study provides a foundation for understanding phytoplankton bloom dynamics and hypoxia formation at a species level.</p>

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Differential dissolved oxygen consumption during the decomposition of seven bloom-forming phytoplankton

  • Se Hee Eom,
  • Hae Jin Jeong,
  • Jin Hee Ok,
  • Ji Hyun You,
  • Sang Ah Park,
  • Hee Chang Kang,
  • Minji Kwon,
  • Yerim Kwon,
  • Chung Yeon Hwang

摘要

Decomposition of bloom-forming organisms often causes coastal hypoxia. To predict hypoxia, the density of a bloom-forming species, its decline rate, and oxygen consumption rate during decomposition should be determined. To determine these parameters, the density of morphologically intact and partially decomposed (PD) cells, and dissolved oxygen (DO) concentrations during a five-day incubation in darkness were measured. Using these data, the decline rate of cell density (kdecline) and oxygen consumption rate per decomposed cell (OCdecomposed cell) of seven bloom-forming species, including diatoms Skeletonema dohrnii, Thalassiosira minuscula and Chaetoceros peruvianus, dinoflagellates Margalefidinium polykrikoides and Tripos furca, and nanoflagellates Teleaulax amphioxeia and Heterosigma akashiwo were calculated. Among the species, Te. amphioxeia had the highest kdecline, 0.66 d− 1, and M. polykrikoides had the highest OCdecomposed cell, 69 pmol O2 cell−1d− 1. kdecline were species-specific and showed no correlation with cell carbon biomass, whereas OCdecomposed cell showed positive correlation with cell carbon biomass. When DO during decomposition of the species were estimated based on kdecline value of (1) intact cells only, (2) intact plus PD0.5 cells, and (3) intact plus PD1 cells, the estimates using intact plus PD0.5 cells for dinoflagellates and intact plus PD1 cells for the others were closest to the measured DO. Furthermore, the Q10 coefficient calculated from the kdecline for S. dohrnii determined at 15 and 25 °C was 3.1. The present study provides a foundation for understanding phytoplankton bloom dynamics and hypoxia formation at a species level.