The 2016 Kaikōura Earthquake has shown that more than 100 million dumptrucks of mud and sand flow through the Kaikōura Canyon every 140 years, scientists say.
Pre and post earthquake morphology of the lower canyon gravel waves. [Images: Dr Joshu Mountjoy, NIWA]
In a paper published today in noted scientific journal Science Advances, lead author NIWA marine geologist Dr Joshu Mountjoy, says the earthquake triggered one of the largest “canyon flushing” events ever documented. Canyon flushing is an event in which high energy currents transport sediment from canyons to the deep ocean.
The paper also reveals the extraordinary impact this event had on the canyon and what was living in it at the time of the 7.8MW quake.
The sediment, calculated by scientists to be at least 850 million tonnes, billowed down from the head of the canyon, through its central channel, wiping out all organisms living in the seabed.
It then travelled along the deep sea Hikurangi Channel and its banks, where scientists took samples of the sediment-flow deposits, known as turbidites, up to 680km northeast of Kaikōura .
Dr Mountjoy said in 2013 everything at the head of the canyon was smooth and draped in mud but investigations two months after the 2016 earthquake revealed that the mud from almost every part of the upper slope had been stripped away.
The paper reveals that the floor of the two main reaches of the Kaikōura Canyon have deepened by up to 50m. In the middle-canyon region, depressions in the bedrock floor have deepened by 20-30m.
Dr Mountjoy says that the impact has been extreme and is the long-term process that shapes submarine canyons.
The results indicate that submarine canyons can cut their way into rock much faster than previously thought with the study providing the first direct evidence of the impacts of a full canyon-flushing event.
Events every 140 years on average
Similar events are calculated to reoccur on average every 140 years, triggered by large earthquakes.
“This study unequivocally demonstrates that earthquake-triggered canyon flushing is the primary process that carves out submarine canyons and delivers coastal sediment to the deep ocean.”
The material removed included seven million tonnes of carbon that is now available to nourish deep sea communities. A NIWA study in September last year found that the former biodiversity hotspot decimated by the earthquake, is now showing signs of recovery with evidence of juvenile animals that once dominated the head of the canyon beginning to colonise the seafloor.
Other studies since the earthquake have revealed it was the most complex quake ever recorded, rupturing more than 21 on and offshore faults along more than 100km, producing widespread coastal uplift, vertical ground movement and numerous landslides.
This study was part of a collaboration between NIWA, Victoria University of Wellington, GNS Science and international colleagues funded by the Natural Hazards Research Platform.
Pre and post earthquake morphology of the canyon rim. [Images: Dr Joshu Mountjoy, NIWA]
Pre and post earthquake morphology of the middle canyon floor. [Images: Dr Joshu Mountjoy, NIWA]