A thin, soft and slippery layer of鈥痗lay-rich mud鈥痚mbedded in rock below the seafloor intensified鈥痶he 2011 Japan鈥痚arthquake that produced鈥痑 tsunami, killing tens of thousands of people and damaging the Fukushima Daiichi nuclear power plant.
The discovery, which is published in the journal , was made by an international team of scientists including researchers from The Australian National University (ANU).
Onboard鈥痶he world鈥檚 most advanced drilling-equipped science vessel,鈥Chikyu, the team 鈥痠n late 2024 to investigate what caused the T艒hoku-oki fault to rupture and trigger鈥痶he earthquake.
The鈥痳esearchers鈥痙rilled up to 7,906 metres below the sea surface, setting a for the deepest scientific ocean drilling ever conducted.
Earth core鈥痵amples recovered from in and around the fault zone reveal that the fault rupture occurred in a layer of clay no more than a few metres thick.
According to ANU geophysicist Associate Professor Ron鈥疕ackney, the clay鈥痠s鈥痸ery soft,鈥痵lippery鈥痑nd exceptionally weak 鈥 a discovery that鈥痺as鈥渟urprising and unusual鈥.
He said this is the first time scientists have linked the presence of soft and slippery clay in a fault plane to ancient sediments deposited on the seafloor over millions of years.
鈥淭his work helps explain why the 2011 earthquake behaved so differently from what many of our models predicted,鈥濃疉ssociate Professor Hackney,鈥痺ho is also鈥疍irector of the Australian and New Zealand International Scientific Drilling Consortium鈥(ANZIC), said.
According to the scientists, learning more about the properties鈥痑nd nature of鈥痑鈥痜ault plane鈥痗an tell them how much of the fault plane might rupture during an earthquake and where the energy released during an earthquake will be concentrated along the fault.
This, in turn,鈥痯rovides鈥痝reater insights into鈥痶he鈥痯rocesses and properties that control giant earthquakes, the resulting movement of the seafloor and tsunami generation, and鈥痶he鈥痩ikely size鈥痑nd extent of any tsunami that might be triggered.
鈥淭his鈥痗lay-rich ancient mud鈥痜ormed from microscopic particles that slowly settled on the seafloor beneath the Pacific Ocean over time 鈥 a process that took place over 130 million years 鈥 as the Pacific tectonic plate slowly moved west to ultimately be forced under Japan,鈥濃疉ssociate Professor鈥疕ackney鈥痵aid.
鈥淭he fault zone formed in that weak layer of clay as those sediments slowly slid under Japan, moving roughly 10 centimetres a year.
"Given that the weak clay layer is sandwiched between stronger layers of rock above and below, the clay acted like a natural 鈥榯ear line鈥 that caused the fault to form within that layer of clay.鈥
The 2011 Japan earthquake was the result of a steady build-up of stress over the hundreds of years since the previous earthquake in a never-ending cycle caused by the movement of the Pacific tectonic plate as it pushed under the tectonic plate on which Japan sits.
According to Associate Professor Hackney, once the built-up stress was abruptly released, the weak nature of the clay offered little resistance to the rupture generated, allowing that rupture to rapidly propagate up the fault, all the way to the seafloor.
This caused the seafloor to rise by several metres, which in turn triggered a tsunami on a scale not expected for this region.
鈥淎mazingly, the fault didn鈥檛 rupture the whole layer of clay, which extends for hundreds of kilometres along the Japan Trench 鈥 the deep ocean boundary where the Pacific and Japan tectonic plates collide with one another,鈥 he said.
鈥淭he rupture plane was just a centimetre or so thick, yet it allowed between 50 and 70 metres of movement on the fault and caused the seafloor off Japan to rise abruptly by several metres during the earthquake.鈥
By learning more about the properties of鈥痶he鈥疶艒hoku-oki鈥痚arthquake鈥痜ault,鈥痵cientists hope to鈥痗onduct鈥痓etter assessments of earthquake and tsunami hazards for coastal communities around the world.
鈥淭here are indications that the sediments being drawn towards and under Sumatra鈥痬ay鈥痑lso鈥痗ontain鈥痑 weak clay layer, which suggests that the giant 2004 Boxing Day tsunami may be linked to鈥痵imilar fault characteristics,鈥 Associate Professor鈥疕ackney said.
"Although we鈥痗an鈥檛鈥痓e sure without extracting and analysing core samples directly from that fault."
The research team has also published鈥痑 taking viewers behind the sciences of their epic鈥痚xpedition.鈥疶he film follows鈥痶he international team of researchers onboard Chikyu as they recover samples from beneath the Japan seafloor.
