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Skip to 0 minutes and 23 secondsMy name is Mike Morley and I'm the geoarchaeologist on the site. And geoarchaeology is a discipline that straddles geography, archeology, and geology. My role on the site is to understand how the site is formed through time, how the layers have been deposited, how the archeology has been preserved at the site, and how changes through time relate to changes in the environment outside of the site, and humans and their role inside of the site. So it's just really getting an understanding of why this site is here, what processes have occurred to actually form this site.

Skip to 1 minute and 4 secondsThis is quite an interesting area of the site because we have a number of layers in here that we can correlate across the layers that we see in the main pit over there where floresiensis remains were found. Layers like these volcanic ash layers are quite interesting because they also show very different changes in sedimentary deposition. So we have volcanic ash layers in here. So we have volcanic events. We have points where there's been a break in deposition. So at some point in the past this was a former ground surface of the shelter. And there's a number of these flow stones that show that there's periods where the sediment has stopped being deposited on this site.

Skip to 1 minute and 47 secondsSo my job really is to understand how did these layers form and what's happened to them since they were deposited. So here we have a schematic cartoon, if you like, of the different depositional environments that we see at Liang Bua. So if we take the first one, the sediments that we see at the base of the sequence were actually deposited by river when the river actually inundated the site and brought in sediment from outside the site. And this happened around about 190,000 years ago. If we move to the second slide, we can see that we have the truncation.

Skip to 2 minutes and 28 secondsRather than the river flowing in through the front, we have water coming in from the rear of the cave through cracks and fissures. That's bringing sediment down from the back of the cave. And essentially because the river has down cut into its floodplain and has now moved away from the site, water traveling from the back of the cave and leaving the site is traveling down slope. And it's actually planing off those river sediments. That process we actually call colluviation. So if we move to the third slide then we can see that we now have the river sediments of the base with this angled surface upon which we have these colluvial sediments sitting on top.

Skip to 3 minutes and 10 secondsSo sometime between 50,000 and 47,000 years ago a volcano has erupted in the vicinity of the site. And during this time clouds of billowing ash coming down into the valley have blown into Liang Bua. And they've covered all of the sediments. So moving on to the fourth slide then, again, we have water that is percolating down from the rear of the cave through cracks and fissures bringing down these fine-grained sediments. And those sediments are largely comprised of silts and clays-- very fine-grained materials. So those fine-grain sediments are actually now covering that volcanic ash. So if we move on to the fifth slide, the catchment area or the region in which Liang Bua is situated is becoming drier.

Skip to 3 minutes and 58 secondsThe main signal we see in fact from the sediments is the roof and the walls of the cave are actually breaking down. And little chunks of limestone and speleothem with stalactites and stalagmites are breaking off the wall and the roof of the cave. So the sediments are much more coarse-grained at this point. And this dry period also happens to coincide with hominins using the cave because we see evidence of fire. And this time the fire isn't from volcanic activity. We're not talking about ash from volcanoes. We're talking about ash from the combustion of wood and leaves and other plant materials. So if you move on to layer six you can see that we have those new layers there.

Skip to 4 minutes and 44 secondsWe can see the yellow layer of the kind of gravels and the material that's broken off the walls and the roof of the cave with these episodic burning episodes contained within that. So now we're getting renewed water flow from the rear of the cave. And this water flow ends up forming what we call a flow stone. It's a bit like a stalactite or a stalagmite. it It's made of solid calcium carbonate. So if you move on to slide number seven, we have evidence of bats roosting in the cave. And when bats roost in a cave they produce lots of bat droppings. Lots of bat droppings can form very thick layers of what we call guano.

Skip to 5 minutes and 25 secondsThe flow stone as we see it today is being very heavily chemically modified. Water has percolated down through the guano and in doing so the water becomes quite acid-loaded. And it's actually leeched the calcium carbonate out of the flow stone beneath and changed it into another mineral form. We can see that optically under the microscope and also using other geochemical techniques. Now if we move on to number eight, we see again there's this switching on of the tap at the back of the caves. We're getting more of this colluviation of fine-grain sediments as they get washed down from the rear of the site.

Skip to 6 minutes and 4 secondsAnd we think during this time as the fine-grain sediments are washed down that the kind of erosive action of that has washed any evidence of that guano away. So we can see that in the last picture, which takes us right up to modern times, you can see the whole sequence there. You can see the river sediments at the base sometime around 190,000 years ago. Then we have the fine-grained colluviation somewhere between 190 and 50, we can't constrain any closer than that. Then we have that red layer which is a volcanic eruption. And then we have some more fine-grained colluviation. Then we have the period where it's much drier at the site.

Skip to 6 minutes and 43 secondsAnd we have hominin activity somewhere around 41,000 to 33,000 years ago. And then we have switched back to this laminar flow. We have these flow stones being formed around 24,000 years ago. And then we have the bat droppings and the stabilization of the site for fine-grained colluviation, all of this occurring sometime over the last 24,000 years, bringing us right up to the modern times.

A Geoarchaeologist's Journey

Dr Mike Morley, a geochronologist, takes us into the pit and explains the role that stratigraphy plays in understanding the history and formation of Liang Bua during and after the life and times of Homo floresiensis.

An examination of the stratigraphy of the cave can shed light on the following questions:

  • How was the Liang Bua deposit formed and how did it change through time?
  • How have the layers been deposited?
  • How has the archaeology been preserved at the site?
  • How do changes through time relate to changes in the environment outside the site, and to the role of humans inside the site?

Mike explains that different layers in the cave provide evidence of a history of volcanic activity (volcanic ash), water flow, fire use (evidence of hominin activity), and evidence of bats roosting (bat droppings/guano) over time.

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This video is from the free online course:

Homo Floresiensis Uncovered: The Science of ‘the Hobbit’

University of Wollongong

Course highlights Get a taste of this course before you join:

  • Why Uncover the Past?
    Why Uncover the Past?

    Professor Bert Roberts explains how modern archaeological science helps us trace out the human story and piece together the human family tree.

  • Excavations at Liang Bua
    Excavations at Liang Bua

    The discovery of Homo floresiensis and ensuing excavations at Liang Bua