86 episodes

What moves the continents, creates mountains, swallows up the sea floor, makes volcanoes erupt, triggers earthquakes, and imprints ancient climates into the rocks? Oliver Strimpel, a former astrophysicist and museum director asks leading researchers to divulge what they have discovered and how they did it.

To learn more about the series, and see images that support the podcasts, go to geologybites.com.
Instagram: @GeologyBites
Twitter: @geology_bites
Email: geologybitespodcast@gmail.com

Geology Bites Oliver Strimpel

    • Science
    • 4.8 • 83 Ratings

What moves the continents, creates mountains, swallows up the sea floor, makes volcanoes erupt, triggers earthquakes, and imprints ancient climates into the rocks? Oliver Strimpel, a former astrophysicist and museum director asks leading researchers to divulge what they have discovered and how they did it.

To learn more about the series, and see images that support the podcasts, go to geologybites.com.
Instagram: @GeologyBites
Twitter: @geology_bites
Email: geologybitespodcast@gmail.com

    Damian Nance on What Drives the Supercontinent Cycle

    Damian Nance on What Drives the Supercontinent Cycle

    Perhaps as many as five times over the course of Earth history, most of the continents gathered together to form a supercontinent. The supercontinents lasted on the order of a hundred million years before breaking apart and dispersing the continents. For decades, we theorized that this cycle of amalgamation and breakup was caused by near-surface tectonic processes such as subduction that swallowed the oceans between the continents and upper mantle convection that triggered the rifting that split the supercontinents apart. As Damian Nance explains in the podcast, newly acquired evidence suggests a very different picture in which the supercontinent cycle is the surface manifestation of a process that involves the entire mantle all the way to the core-mantle boundary.



    Damian Nance draws on a wide range of geological evidence to formulate theories about the large-scale dynamics of the lithosphere and mantle spanning a period going back to the Archean. A major focus of his research is the supercontinent cycle. He is Distinguished Professor Emeritus of Geological Sciences at Ohio University.

    • 35 min
    David Kohlstedt on Simulating the Mantle in the Lab

    David Kohlstedt on Simulating the Mantle in the Lab

    The Earth’s tectonic plates float on top of the ductile portion of the Earth’s mantle called the asthenosphere. The properties of the asthenosphere, in particular its viscosity, are thought to play a key role in determining how plates move, subduct, and how melt is produced and accumulates. We would like to know what the viscosity of the the asthenosphere is, and how it depends on temperature, pressure, and the proportion of melt and water it contains. Few mantle rocks ever reach the Earth’s surface, and those that do are altered by weathering. So, as he explains in the podcast, David Kohlstedt and his team have tried to replicate the rock compositions and physical conditions of the mantle in the lab. Using specially-built apparatus, he has been able to determine the viscosity of the asthenosphere to within an order of magnitude, which is an enormous improvement on what was known before.

    David Kohlstedt is Professor Emeritus at the School of Earth and Environmental Science at the University of Minnesota.

    • 32 min
    Claire Corkhill on Geological Radioactive Waste Disposal

    Claire Corkhill on Geological Radioactive Waste Disposal

    In many countries, nuclear power is a significant part of the energy mix being planned as part of the drive to achieve net-zero greenhouse-gas emissions. This means that we will be producing a lot more radioactive waste, some of it with half-lives that approach geological timescales, which are orders of magnitude greater than timescales associated with human civilizations. In the podcast, Claire Corkhill discusses the geology such storage sites require, some new materials that can confine radioactive isotopes over extremely long timescales, and the kind of hazards, including human, we need to guard against.


    Claire Corkhill is Professor of Mineralogy and Radioactive Waste Management in the School of Earth Sciences at the University of Bristol, UK.

    • 31 min
    Mahesh Anand on What Human Return to the Moon Means for Lunar Geology

    Mahesh Anand on What Human Return to the Moon Means for Lunar Geology

    We have learned a great deal about the geology of the Moon from remote sensing instruments aboard lunar orbiters, from robot landers, from the Apollo landings, and from samples returned to the Earth by Apollo and robot landings. But in 2025, when NASA plans to land humans on the Moon for the first time since 1972, a new phase of lunar exploration is expected to begin. What will this mean for our understanding of the origin, evolution, and present structure of the Moon? A lot, according to Mahesh Anand. For example, as he explains in the podcast, satellite imagery suggests that volcanism continued for much longer than was previously thought, perhaps until as recently as 100 million years ago. In-situ inspection and sample return should help us explain this surprising finding.

    Mahesh Anand is Professor of Planetary Science and Exploration at the Open University, UK.

    • 32 min
    Susan Brantley on Earth's Geological Thermostat

    Susan Brantley on Earth's Geological Thermostat

    At the core of Earth’s geological thermostat is the dissolution of silicate minerals in the presence of atmospheric carbon dioxide and liquid water. But at large scales, the effectiveness and temperature sensitivity of this reaction depends on geomorphological, climatic, and tectonic factors that vary greatly from place to place. As described in the podcast, to predict watershed-scale or global temperature sensitivity, Susan Brantley characterizes these factors using the standard formula for the temperature dependence of chemical reaction rates using an empirically-determined activation energy for each process. Overall, her results suggest a doubling of the weathering rate for each 10-degree rise in temperature, but this value changes with the spatial scale of the analysis.



    Susan Brantley is a Professor in the Department of Geosciences at Pennsylvania State University.

    • 27 min
    Clark Johnson on the Banded Iron Formations

    Clark Johnson on the Banded Iron Formations

    Banded Iron Formations (BIFs) are a visually striking group of sedimentary rocks that are iron rich and almost exclusively deposited in the Precambrian. Their existence points to a major marine iron cycle that does not operate today. Several theories have been proposed to explain how the BIFs formed. While they all involve the precipitation of ferric (Fe3+) iron hydroxides from the seawater via oxidation of dissolved ferrous (Fe2+) iron that was abundant when the oceans contained very low levels of free oxygen, they disagree as to how this oxidation occurred. In the podcast, Clark Johnson describes how oxidation could have occurred without the presence of abundant free oxygen in the oceans.

    Clark Johnson is a Professor Emeritus in the Department of Geoscience at the University of Wisconsin-Madison.

    • 28 min

Customer Reviews

4.8 out of 5
83 Ratings

83 Ratings

MTrudnak ,

Awesome pod!

This podcast has very quickly become one of my favorites. Diverse range of topics and all extremely engaging!

Thanks Oliver.

Huachuca Rock Hound ,

High level content

This is not a dumbed down version of earth science topics but rather a high level discussion of important topics in the field of geology. Absolutely outstanding!

kristi history ,

Thank you

I LOVE this podcast. Pure science no agenda.

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