Image copyright NASA

The Falkland Islands may at some point in the future face a major tsunami.

Scientists have found evidence of ancient slope failures on the seafloor to the south of the British Overseas Territory.

Computer models suggest these underwater landslides would have been capable of sending waves crashing on to the Falklands' coastline that were tens of metres high.

Fortunately, such events only appear to happen once every million years or so.

That means islanders shouldn't stay awake at night worrying about them, says Dr Uisdean Nicholson who's been investigating the issue.

Media playback is unsupported on your device Media caption Uisdean Nicholson: "The tsunami would take about an hour to reach the Falklands"

"But you do want to capture risks at a range of different timescales. So I definitely think we should do more research to understand the different ways these events might be triggered," the Heriot-Watt University geologist told BBC News.

Sub-Antarctic Front (SAF) passes through a narrow channel on the seafloor called the 54-54 Passage and accelerates to the northwest

The fast-moving jet of water erodes the edge of Burdwood Bank, picking up silt and sand which it carries westwards

The SAF encounters an offshoot jet known as the Sub-Antarctic Mode Water (SAMW) and slows down, dumping its sediment load

Sediment builds on a steep slope on the northern edge of Burdwood Bank. Eventually, it collapses, perhaps shaken by a quake

The underwater landslides generate tsunami that head towards the Falkland Islands. Southern shores could witness 40m-high waves

The submarine landslides all occurred in the same location - on steeply inclined terrain on the edge of a raised region of the seafloor known as Burdwood Bank.

Seismic data reveals examples of repeat sediment failure where mud, sand and silt has tumbled down-slope into deeper waters.

The volume of material involved for the larger events appears to be around 100 cubic km.

"That's approximately the same as if you were to cover the whole area of Edinburgh, right out to the bypass, with 400m of sediment. You would cover Arthur's Seat," the Scottish scientist explained.

Nearby exploratory drilling by oil companies and scientific expeditions has allowed the team, which includes the British Geological Survey (BGS) and University College London, to roughly date the sediments and constrain the frequency of the slope failures.

Three or four of the "Edinburgh-sized" slides have occurred in the last three million years.

Image copyright Getty Images Image caption Sense of scale: Arthur's Seat, the extinct volcano in Edinburgh, is 250m high

Everyone knows now that certain types of giant earthquake will trigger ocean tsunami by pushing up or depressing the column of water directly above a rupture in the seafloor.

Less well recognised is that sudden slumping of sediment in underwater landslides will achieve the same effect.

A recent example includes the September 2018 event at the Indonesian island of Sulawesi where a quake set off a number of submarine slope failures that then directed two-metre high waves at the city of Palu.

And in 1998, a submarine landslide sent 15m-high waves on to Papua New Guinea that killed 2,200 people.

Landslide-induced waves can be very big indeed, especially close to the source - although their energy tends to fall off quickly with distance.

The Falklands are about 150km from Burdwood Bank. Even so, the modelling suggests the larger slope failures could produce waves as high as 40m on the territory's southern shoreline, and perhaps as tall as 10m at the capital, Port Stanley.

"We must stress these are old events that we've looked at; we don't want to put the fear of God into people," said BGS Prof Dave Tappin. "But the more events and case histories we study - even if they are millions of years old or a hundred thousand years old - the better we can understand not only how such tsunami are generated but also their likely future hazard."

Media playback is unsupported on your device Media caption Scientists have modelled how submarine landslides could produce a tsunami

One puzzle for the team has been to explain how a particular location on Burdwood Bank turned into such a prolific "landslide factory", and the scientists think they do now have a persuasive narrative.

It involves the Sub-Antarctic Front (SAF), the northern-most branch, or jet, of the Antarctic Circumpolar Current (ACC).

The ACC is the most powerful movement of water on Earth and where the SAF skirts the bank it can be accelerated in places so that it becomes a highly erosive force.

The front will be picking up sediment at one location and then dumping it at another.

This accumulation site, dubbed Burdwood Drift, is the high, steep slope evident in the seismic data.

The emplaced silt and sand is clearly growing again but it's impossible right now for anyone to say if or when another slide might occur.

Internal instabilities could eventually activate the slope, but a more seeming scenario is that shaking from a local quake provokes a collapse of the sediment. After all, the bank is relatively close to tectonic plate boundaries.

Future research would involve digging on the Falklands to try to find deposits from ancient tsunami.

"You maybe even want to sample the drift to see what it consists of, what the shear strength of the material is; and then you can put all this information into your models to refine them," said Dr Nicholson.

Prof Dan Parsons is director of the Energy and Environment Institute at Hull University. His group studies submarine landslides and comments that the consequences of these phenomena are little appreciated.

"The impacts on both tsunami generation and also the impact on sub-sea infrastructure can be significant," he told BBC News.

"The vast majority of our internet connectivity is piped through fibre cables laying across the sea-floor - in essence, the cloud is at the bottom of the sea. These cables can be, and are, broken by sub-sea movements, failures and flows - and that can be as impactful in terms of national security as a large tsunami."

The current study is reported in the journal Marine Geology.

Jonathan.Amos-INTERNET@bbc.co.uk and follow me on Twitter: @BBCAmos