Effect of elevated CO2 and small boat noise on the kinematics of predator-prey interactions

This dataset is available as a spreadsheet in MS Excel (.xlsx) and Open Document formats (.ods) Abstract [Related Publication]: Oceans of the future are predicted to be more acidic and noiser, particularly along the productive coastal fringe. This study examined the independent and combined effects...

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Bibliographic Details
Other Authors: Mark Ian McCormick (hasCollector), Bridie Jean Marie Allan (hasCollector), Mark Ian McCormick (hasAssociationWith), Sue-Ann Watson (hasCollector)
Format: Dataset
Language:unknown
Published: James Cook University
Subjects:
anthropogenic noise
ocean acidification
escape response
predator-prey
coral reef fish
marine ecology
ARC Centre of Excellence for Coral Reef Studies
Community Ecology
BIOLOGICAL SCIENCES
ECOLOGY
Behavioural Ecology
Expanding Knowledge in the Biological Sciences
EXPANDING KNOWLEDGE
Lizard Island
Ocean acidification
Online Access:https://doi.org/10.1098/rspb.2017.2650
https://researchdata.edu.au/effect-elevated-co2-prey-interactions/992560
https://research.jcu.edu.au/data/published/1708374a9d89386deada0b62f2b7a894
https://doi.org/10.4225/28/5a1cd71b4ef8a
Description
Summary:This dataset is available as a spreadsheet in MS Excel (.xlsx) and Open Document formats (.ods) Abstract [Related Publication]: Oceans of the future are predicted to be more acidic and noiser, particularly along the productive coastal fringe. This study examined the independent and combined effects of short-term exposure to elevated CO2 and boat noise on the predator–prey interaction of a pair of common coral reef fishes (Pomacentrus wardi and its predator, Pseudochromis fuscus). Successful capture of prey by predators increased from ambient control conditions with the addition of either playback of boat noise or elevated CO2 (925 µatm). The coincidence of both stressors led to lower capture rates that were similar to the controls, suggesting an interaction between CO2 levels and noise levels on predator success. The kinematics were the same for all stressor combinations and differed from the controls. The effects of CO2 or boat noise were the same suggesting that their effects were substitutive in this situation. Prey reduced their perception of threat under both stressors individually and when combined, and this coincided with reduced predator attack distances and attack speeds. The present findings of an interaction among future stressors highlights the importance of determining the combined effects of key drivers to aid in predicting community dynamics under future environmental scenarios. The full methodology is available in the publication shown in the Related Publications link below.

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