This short visual film about the geology of the beautiful Dolomites mountain range is created by Italian photographer/filmmaker Rolando Menardi. These unspoiled mountains straddle the territory of five provinces in northeastern Italy, forming part of the Southern Limestone Alps. One of its provinces, South Tyrol, is home to the South Tyrol Museum of Archaeology, where one can visit the ancient 5,000-year-old preserved Otzi, the Iceman.
“The surface of the earth is far more beautiful and far more intricate than any lifeless world. Our planet is graced by life and one quality that sets life apart is its complexity.” –Carl Sagan
The stratigraphy of the Dolomites includes Permian to Cretaceous terrains which sit on top of a Paleozoic Basement. Although the sedimentary succession ranges through these periods, the landscape is dominated by the majestic Triassic carbonates. The birth of the Dolomites can be traced back to the womb of Tethys Sea, germinating from its sediments and calcareous deposits. The Dolomites entered UNESCO’s World Heritage List in 2009.
This is a separate video below, depicting the scenic rich Dolomites from the South Tyrol province:
In the shadows of Nevado Coropuna—Peru’s tallest volcano—geologist Gordon Bromley quietly hacks away at glacial deposits. He is collecting samples from boulders that skated down the mountain during the last ice age. These samples will be processed by a technique called surface exposure dating. In a concerted project with Columbia University’s Lamont-Doherty Earth Observatory, they will isolate the tiny grains of the mineral pyroxene to measure its helium isotopes. This will be crucial to reconstructing the ebb and flow of ice on Nevado Coropuna since the last ice age, to understand when glaciers on Coropuna advanced and retreated, how the tropics influenced the global climate system, and agricultural impacts in the area.
Kurt Rademaker, an archaeologist from the University of Maine, helps Bromley with geology work. During a five hour walk into a lava field, they discovered stones that were clearly not natural deposits. It turned out to be an ancient Andean road. At roughly 15,000 feet, they further discovered a prehistoric rock shelter – the highest ice age archaeological site known thus far. Rademaker has found evidence of human activity that reaches back to the end of the last ice age. He has found numerous artifacts that were radio carbon dated to 12,000 years ago and based on archaeological evidence, he suggests that the last event in the shelter was cooking before the inhabitants hurriedly left the site.
Together with glacial geologic chronology, they are establishing precisely when humans occupied and unoccupied the site. This will shed understanding on why those humans left – what were they responding, a change in the local environment? So far, their research findings challenge conventional thinking that the climate was too cold for early hunter-gatherers to survive.
The concerted project seeks to understand the past climate better, along with wanting to understand what adaptation measures may help humans survive in this hotter world. Archaeology in collaboration with geology will help answer such questions. Archaeology can provide another layer of evidence in reconstructing the ebb and flow of ice on Coropuna. While geology seeks to understand paleo-climate to understand the future and impact on humans, archaeology can yet provide supporting evidence on how climate impacted past humans.
Coropuna has seen the dissipation of snow twice, once in the last ice age, and in modern day. Temperatures are rising due to industrious carbon dioxide in the air. Coropuna is changing again. It has lost a quarter of its glacier mass since the 1960s. Millions of humans rely on glacial water and water in the arid region is expected to grow even scarcer. Understanding the ebb and flow of Coropuna’s glaciers in the past will be a key to understanding how a rapidly warming climate will impact water availability in the future. Research is still ongoing.