Rising Seas Could Shrink Australia #auspol #ClimateChange #StopAdani

How rising sea levels could shrink Australia and spark a coastal exodus

By Sean Ulm, Alan Williams, Chris Turney and Stephen Lewis

PHOTO Australia’s coastline has moved before thanks to changes in sea level.Flickr: Travellers Travel Photobook, CC BY 2.0

With global sea levels expected to rise by up to a metre by 2100, we can learn much from archaeology about how people coped in the past with changes in sea level.

In a study published this week in Quaternary Science Reviews, we looked at how changes in sea level affected different parts of Australia and the impact on people living around the coast.

The study casts new light on how people adapt to rising sea levels of the scale projected to happen in our near future.

Living on the coast

More than eight out of every 10 Australians live within 50 kilometres of the coast.

The Intergovernmental Panel on Climate Change says global sea levels are set to increase by the equivalent of 12 millimetres per year, four times the average of the last century.

A major challenge for managing such a large increase in sea level is our limited understanding of what impact this scale of change might have on humanity.

While there are excellent online resources to model the local physical impacts of sea level rise, the recent geological past can provide important insights into how humans responded to dramatic increases in sea level.

The last ice age

At the height of the last ice age some 21,000 years ago, not only were the Greenland and Antarctic ice sheets larger than they are today, but three-kilometre-high ice sheets covered large parts of North America and northern Europe.

This sucked vast amounts of water out of our planet’s oceans. The practical upshot was the sea level was about 125 metres lower, making the shape of the world’s coastlines distinctly different to today.

As the world lurched out of the last ice age with increasing temperatures, the melting ice returned to the ocean as freshwater, dramatically increasing sea levels and altering the surface of our planet.

Arguably nowhere experienced greater changes than Australia, a continent with a broad continental shelf and a rich archaeological record spanning tens of millennia.

A bigger landmass

For most of human history in Australia, lower sea levels joined mainland Australia to both Tasmania and New Guinea, forming a supercontinent called Sahul.

The Gulf of Carpentaria hosted a freshwater lake more than twice the size of Tasmania (about 190,000 square kilometres).

Our study shows that lower sea levels resulted in Australia growing by almost 40 per cent during this time — from the current landmass of 7.2 million square kilometres to 9.8 million square kilometres.

The coastlines also looked very different, with steep profiles off the edge of the exposed continental shelf in many areas forming precipitous slopes and cliffs.

Imagine the current coastline where the Twelve Apostles are on Victoria’s Great Ocean Road and then extend them around much of the continent.

Many rivers flowed across the exposed shelf to the then distant coast.

The 12 Apostles Great ocean road Victoria

When things warmed up

Then between 18,000 and 8,000 years ago, global climate warmed, leading to rapid melting of the ice sheets, and seeing sea levels in the Australian region rising from 125 metres below to two metres above modern sea levels.

Tasmania was cut off with the flooding of Bass Strait about 11,000 years ago. New Guinea was separated from Australia with the flooding of Torres Strait and creation of the Gulf of Carpentaria around 8,000 years ago.

We found that 2.12 million square kilometres, or 20–29 per cent of the landmass — a size comparable to the state of Queensland — was lost during this inundation.

The location of coastlines changed on average by 139 kilometres inland. In some areas the change was more than 300 kilometres.

Much of this inundation occurred over a 4,000-year period (between 14,600 and 10,600 years ago) initiated by what is called Meltwater Pulse 1A, a period of substantial ice sheet collapse releasing millions of cubic litres of water back into the oceans.

During this period, sea levels rose by 58 metres, equivalent to 14.5 millimetres per year. On the ground, this would have seen movement of the sea’s edge at a pace of about 20–24 metres per year.

Impacts of past sea level rise

The potential impacts of these past sea-level changes on Aboriginal populations and societies have long been a subject of speculation by archaeologists and historians.

Photo: Map of Australia showing sea-level change and archaeological sites for selected periods between 35,000 and 8,000 years ago. (Supplied: Sean Ulm)

In his 1970s book Triumph of the Nomads: A History of Aboriginal Australia, the Australian historian Geoffrey Blainey hypothesised that:

“Most tribal groups on the coast 18,000 years ago must have slowly lost their entire territory […] a succession of retreats must have occurred. The slow exodus of refugees, the sorting out of peoples and the struggle for territories probably led to many deaths as well as new alliances.”

Archaeologists have long recognised that Aboriginal people would have occupied the now-drowned continental shelves surrounding Australia, but opinions have been divided about the nature of occupation and the significance of sea-level rise.

Most have suggested that the ancient coasts were little-used or underpopulated in the past.

Our data shows Aboriginal populations were severely disrupted by sea-level change in many areas.

Perhaps surprisingly the initial decrease in sea level prior to the peak of the last ice age resulted in people largely abandoning the coastline, and heading inland, with a number of archaeological sites within the interior becoming established at this time.

During the peak of the last ice age, there is evidence on the west coast that shows people continued to use marine resources (shellfish, fish etc) during this time, albeit at low levels.

Photo: Fish traps at Oyster Harbour, near Albany. (Supplied: South Coast NRM)

A shrinking landmass

With the onset of the massive inundation after the end of the last ice age, people evacuated the coasts causing markedly increased population densities across Australia (from about 1 person for every 355 square kilometres 20,000 years ago, to 1 person every 147 square kilometres 10,000 years ago).

Rising sea levels had such a profound impact on societies that Aboriginal oral histories from around the length of the Australian coastline preserve details of coastal flooding and the migration of populations.

We argue that this squeezing of people into a landmass 22 per cent smaller — into inland areas that were already occupied — required people to adopt new social, settlement and subsistence strategies.

This may have been an important element in the development of the complex geographical and religious landscape that European explorers observed in the 18th and 19th centuries.

Following the stabilisation of the sea level after 8,000 years ago, we start to see the onset of intensive technological investment and manipulation of the landscape (such as fish traps and landscape burning).

We also see the formation of territories (evident by marking of place through rock art) that continues to propagate up until the present time. All signs of more people trying to survive in less space.

So what are the lessons of the past for today? Thankfully, we can show that past societies survived rapid sea level change at rates slightly greater than those projected in our near future, albeit with population densities far lower than today.

But we can also see that sea level rise resulted in drastic changes to where people lived, how they survived, what technology they used, and probable modifications to their social, religious and political ways of life.

In today’s world with substantially higher population densities, managing the relocation of people inland and outside Australia, potentially across national boundaries, may provide to be one of the great social challenges of the 21st century.

Sean Ulm is deputy director at the ARC Centre of Excellence for Australian Biodiversity and Heritage, James Cook University.

Alan N Williams is an associate investigator at the ARC Centre of Excellence for Australian Biodiversity and Heritage, UNSW.

Chris Turney is chief investigator at the ARC Centre of Excellence for Australian Biodiversity and Heritage, UNSW.

Stephen Lewis is principal research officer at James Cook University.

Originally published in The Conversation

Press link for more: ABC.NET.AU

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4 comments

  1. The Nile Delta would also be vulnerable to rising oceans.
    The timescales discussed are very recent and short with regard to the bigger picture.
    What I’m trying to say is change can be very fast even in one lifetime.
    Politicians and CEOs of companies do not appreciate the current urgency in containing CO2; NH4 and Mg gas growth from coal
    Mines Fracking and Oil drilling.
    Nor do they want to accept the extreme dangers associated with the nuclear fuel cycle including transport of nuclear waste accidents and mistakes that will be made by humans.
    These things threaten all living things yet the idiots persist in wanting to play with nuclear fire!

    Liked by 1 person

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