Combating climate change with olivine

  • Author(s)
    Professor Tim Flannery
  • Category
    AMRI
  • Published
    12 March 2024
  • Read time
    2 minutes

Australia is very rich in silicate rocks, which may hold the key to unlocking new climate solutions. As world leaders in mining technology, we have the capacity to lead the charge in using silicate rocks to absorb CO2 establishing Australia not only as a leader in renewable systems, but also nature-based climate solutions. Below, Tim Flannery discusses an exciting mineral, olivine, and how it can be used to tackle climate change.

When I was about 16 years old, I was quite taken by a farmer who collected rocks from a scoria (a volcanic rock) quarry on the side of a volcano. He picked up a piece of lava which was around the size and shape of a football; a ‘volcanic bomb’ which had been ejected out of the volcano when it had last erupted thousands of years ago. He broke the bomb open, and in the centre glowed a mass of beautiful green crystals. This was olivine, which the volcano had brought up from Earth’s upper mantle, then ejected with great force - the lava surrounding it solidifying into its distinctive shape as it flew. The Australian Museum has specimens in its collection from a volcano in Western Victoria which is very similar to the one I saw (Figure 1).

Figure 1. DR.19319 Olivine in volcanic bomb from the Australian Museum collection
Figure 1. DR.19319 Olivine in volcanic bomb from the Australian Museum collection. Image: Ross Pogson
© Australian Museum

Peridot is another name for the crystalline mineral most commonly known as olivine. Olivine is just one of a group of minerals known as silicates, which all share a characteristic that makes them important in the fight against climate change. As olivine rocks decompose, they absorb atmospheric CO2 and bind it into carbonates in the soil, thereby removing it permanently from the atmosphere. Olivine and some other silicate minerals are so efficient at capturing CO2 as they degrade that less than a litre of crushed olivine can capture the CO2 released by burning a litre of oil. To capture carbon, atmospheric CO2 must combine with water to create carbonic acid. When this acid interacts with silicate minerals it triggers an Urey reaction[1], which traps the CO2 in soil carbonates.

While the Earth was still young and its atmosphere filled with CO2, the Urey reaction reduced atmospheric CO2 to levels that made the planet habitable. Over geological time, the Urey reaction responds to planetary warmth and balances the release and absorption of CO2, keeping atmospheric CO2 at low levels. The Urey reaction will eventually absorb the CO2 that humans have put into the atmosphere, but that will take hundreds of thousands of years – too long to save us from catastrophic climate change. What we need is to speed up the Urey reaction; but how?

Photo
Ross Pogson, Mineralogist, AMRI, with a specimen of olivine, 2022. Image: Tim Flannery
© Australian Museum

Some scientists think that olivine and related minerals might be the answer to combatting climate change. In the coming decades, we will need to draw vast volumes of CO2 out of the atmosphere, and silicate rocks like olivine offer one of the most efficient ways of doing so. These scientists estimate that if we of it, crush it up and spread it on Earth’s beaches and agricultural fields, we could speed up the Urey reaction and be drawing down gigatons of atmospheric CO2 by 2100.[2]

Unfortunately, there is an impediment: to use these rocks, they must be blasted, transported and crushed to the consistency of sand, a process which currently burns a great deal of fossil fuel. Most of the CO2 emissions associated with using silicate rocks come from transport. In one study where the rock quarry was 65km from the field where the crushed rock was spread, the process took 110g of CO2 emissions for every kilogram of CO2 removed from the atmosphere.[2] But the study warns that if the rock needs to be transported more than around 600km, then as much CO2 will be emitted as the rock will absorb. Until we can use clean energy to quarry and crush silicate rocks, we can’t take full advantage of their amazing ability to absorb CO2 and store it in the earth.

Figure 3. DR. 19319 Olivine in a volcanic bomb from the Australian Museum mineralogy collection.
Figure 3. DR. 19319 Olivine in a volcanic bomb from the Australian Museum mineralogy collection. Image: Ross Pogson
© Australian Museum

Australia is very rich in silicate rocks, and we are world leaders in mining technology. We also have an exceptionally large agricultural industry. In addition to absorbing carbon from our atmosphere, minerals like olivine return elements to depleted soils, benefiting agricultural operations.[4] A recent study has shown that if we added crushed basalt to the agricultural land of China, India, the United States and Brazil, we would draw down 2 gigatonnes of CO2 per year![5] When the benefits of using this material are so varied, it is a wonder why we are not improving our mining operations to maximize the use of silicate rocks. If we green our energy and transport systems quickly, we could become a world leader in using silicate rocks to absorb CO2. Thus, olivine may hold the key to establishing Australia as a leader in renewable, nature-based climate solutions.

Footnotes:

  1. “The basic reaction combines atmospheric CO2 with a calcium silicate to generate a calcium carbonate plus silica”, as described in Kellogg et al (2019)
  2. Holzer, I.O., Nocco, M.A. and Houlton, B.Z., 2023. Direct evidence for atmospheric carbon dioxide removal via enhanced weathering in cropland soil. Environmental Research Communications, 5(10), p.101004.
  3. LeFebre, D. et al. 2019. Assessing the potential of soil carbonation and enhanced weathering through Life Cycle Assessment: A case study for Sao Paulo State, Brazil. Journal of Cleaner Production. 233, 468-481.
  4. Power, I. M. et al., ‘Sperpentinite Carbonation for CO2 Sequestration, Geoscience World 9, 2, 115–121, 2013, elements.geoscienceworld.org/content/9/2/115.short
  5. Beerling, D.J., Kantzas, E.P., Lomas, M.R., Wade, P., Eufrasio, R.M., Renforth, P., Sarkar, B., Andrews, M.G., James, R.H., Pearce, C.R. and Mercure, J.F., 2020. Potential for large-scale CO2 removal via enhanced rock weathering with croplands. Nature, 583(7815), pp.242-248.

References:

  • Beerling, D.J., Kantzas, E.P., Lomas, M.R., Wade, P., Eufrasio, R.M., Renforth, P., Sarkar, B., Andrews, M.G., James, R.H., Pearce, C.R. and Mercure, J.F., 2020. Potential for large-scale CO2 removal via enhanced rock weathering with croplands. Nature, 583(7815), pp.242-248.
  • Holzer, I.O., Nocco, M.A. and Houlton, B.Z., 2023. Direct evidence for atmospheric carbon dioxide removal via enhanced weathering in cropland soil. Environmental Research Communications, 5(10), p.101004.
  • Kellogg LH, Turcotte DL and Lokavarapu H (2019) On the Role of the Urey Reaction in Extracting Carbon From the Earth's Atmosphere and Adding It to the Continental Crust. Front. Astron. Space Sci. 6:62. doi: 10.3389/fspas.2019.00062
  • Power, I. M. et al., ‘Sperpentinite Carbonation for CO2 Sequestration, Geoscience World 9, 2, 115–121, 2013, elements.geoscienceworld.org/content/9/2/115.short
  • Urey, H. C. (1952a). On the early chemical history of the earth and the origin of life. Proc. Natl. Acad. Sci. U.S.A. 38, 351–363. doi: 10.1073/pnas.38.4.351