Recovery of deep-sea meiofauna community in Kaikōura Canyon following an earthquake-triggered turbidity flow

Katharine T Bigham; Daniel Leduc; Ashley A Rowden; David A Bowden; Scott D Nodder; Alan R Orpin

doi:10.7717/peerj.17367

Recovery of deep-sea meiofauna community in Kaikōura Canyon following an earthquake-triggered turbidity flow

PeerJ. 2024 Jun 25:12:e17367. doi: 10.7717/peerj.17367. eCollection 2024.

Authors

Katharine T Bigham^{1

2}, Daniel Leduc², Ashley A Rowden^{1

2}, David A Bowden², Scott D Nodder², Alan R Orpin²

Affiliations

¹ School of Biological Sciences, Victoria University of Wellington, Wellington, New Zealand.
² National Institute of Water and Atmospheric Research, Wellington, New Zealand.

Abstract

Turbidity flows can transport massive amounts of sediment across large distances with dramatic, long-lasting impacts on deep-sea benthic communities. The 2016 M_w 7.8 Kaikōura Earthquake triggered a canyon-flushing event in Kaikōura Canyon, New Zealand, which included significant submarine mass wasting, debris, and turbidity flows. This event provided an excellent opportunity to investigate the effects of large-scale natural disturbance on benthic ecosystems. Benthic meiofauna community structure before and after the event was analysed from a time series of sediment cores collected 10 years and 6 years before, and 10 weeks, 10 months, and 4 years after the disturbance. Immediately after the 2016 event abundances of all meiofauna dramatically decreased. Four years later the meiofauna community had recovered and was no longer distinguishable from the pre-event community. However, the nematode component of the community was similar, but not fully comparable to the pre-event community by 4 years after the disturbance. Community recovery was systematically correlated to changes in the physical characteristics of the habitat caused by the disturbance, using physical and biochemical variables derived from sediment cores, namely: sediment texture, organic matter, and pigment content. While these environmental variables explained relatively little of the overall variability in meiofauna community structure, particle size, food availability and quality were significant components. The minimum threshold time for the meiofauna community to fully recover was estimated to be between 3.9 and 4.7 years, although the predicted recovery time for the nematode community was longer, between 4.6 and 5 years. We consider the management implications of this study in comparison to the few studies of large-scale disturbances in the deep sea, in terms of their relevance to the efficacy of the marine reserve that encompasses Kaikōura Canyon, along with potential implications for our understanding of the impacts of anthropogenic seafloor disturbances, such as seabed mining.

Keywords: Deep Sea; Disturbance; Meiofauna; Recovery; Resilience; Submarine canyon; Turbidity flow.

MeSH terms

Animals
Earthquakes*
Ecosystem
Geologic Sediments*
Invertebrates / physiology
New Zealand

Grants and funding

Funding for this project came from NOAA Ocean Exploration and NIWA, with co-funding from Woods Hole Oceanographic Institution, Scripps Oceanographic Institution, and the University of Hawaii (TAN0616), predecessors of the present New Zealand Government research funding agency, the Ministry of Business, Innovation and Employment, via the Ocean Ecosystems programme (TAN1006), New Zealand Ministry for Primary Industries with additional funding from NIWA Strategic Science Investment Fund (SSIF) project COES1701 (TAN1701), NIWA SSIF and Tangaroa Reference Group (TRG) (TAN1707), NIWA’s Coast & Oceans Centre and TRG (TAN1708), NIWA SSIF program COPR, TRG, and Eurofleets+ (TAN2011). Katharine T. Bigham was supported by a NIWA-VUW PhD scholarship in marine sciences. The funders had no role in study design, data collection and analysis, decision to publish, or preparation of the manuscript.