FeO is a compound of great interest in condensed matter physics and geophysics. It has complex and subtle structural, magnetic, and electronic transitions. It has been challenging for theoretical/computational methods to address such property changes in a prototypical, strongly correlated material such as FeO. This paper shows that the fundamental properties of FeO can be described successfully at high pressures and temperatures by a standard density-functional-based method once its dynamic complexity and electronic excitations are addressed simultaneously.
This work establishes the theoretical framework to predict the properties of iron alloys at the extreme thermodynamic conditions of the Earth’s core, an enigmatic planet region. This framework should be a starting point for investigating the properties of other alleged strongly correlated materials at more normal thermodynamic conditions.
Several theoretical/computational methods needed to be developed to address diverse challenges before a full-scale simulation of this complex material could be performed successfully under such extreme pressure and temperature conditions. The authors used a novel combination of approaches and methods developed in-house to perform these simulations. – Renata Wentzcovitch
Photonics Focus Magazine Vol. 4 Issue 3 Probing the quantum Earth |
A quantum phase transition called spin crossover can be used to visualize deep-Earth processes like subducting tectonic plates. Photo credit: Nature Communications
Shephard, G.E., Houser, C.,et al., Wentzcovitch, R.M., Seismological expression of the iron spin crossover in ferropericlase in the Earth’s lower mantle. Nat Commun 12, 5905 (2021). https://doi.org/10.1038/s41467-021-26115-z
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A new study investigates iron’s form at the planet’s interior. The findings have repercussions for understanding the inner core’s structure.
Y. Sun, M. I. Mendelev, F. Zhang, Z. Liu, B. Da, C.-Z Wang, R. M. Wentzcovitch, and K.-M. Ho. Geophys. Res. Lett. (2023). https://doi.org/10.1029/2022GL102447
Earth’s inner core is dominated by iron, which can exist as a solid material in more than one crystallographic form. (This quality allows iron to combine with other elements to form alloys.) Iron’s most stable form at room temperature is the body-centered cubic (bcc) structure. At extremely high pressures, it is stable in its hexagonal close-packed (hcp) phase. Of considerable debate, however, is iron’s structure at the center of Earth. In a new study, Sun et al. get one step closer to an answer.
J. Liu, Y. Sun, C. Lv, F. Zhang, S. Fu, V. B. Prakapenka, C.-Z. Wang, K.-M. Ho, J.-F. Lin, R. M. Wentzcovitch. The Innovation (2022). https://doi.org/10.1016/j.xinn.2022.100354
Oxygen is the key substance for life and one of the most abundant elements in the Earth. However, it’s still unknown whether oxygen is present and in which form in the inner core with extreme high pressure and temperature conditions, and almost composed of pure iron. Scientists co-led by Dr. Jin Liu from HPSTAR (the Center for High Pressure Science &Technology Advanced Research) and Dr. Yang Sun from Columbia University reveal that Fe-rich Fe-O alloys are stable at extreme pressures of nearly 300 GPa and high temperatures of more than 3,000 K. The results published in the journal of The Innovation prove that oxygen can exist in the solid inner core, which provides key constraints for further understanding of the formation process and evolution history of the Earth’s core.
Is the Earth’s inner core so “anoxic?” To answer this question, a series of experiments and theoretical calculations were carried out in this study.
To be close to the temperature and pressure of Earth’s core, pure iron and iron oxide were placed on the tips of two diamond anvils and heated with a high-energy laser beam. After many attempts, it was found that a chemical reaction between iron and iron oxide occurs above 220–260 GPa and 3,000 K. The XRD results reveal that the reaction product is different from the common high-temperature and high-pressure structure of pure iron and iron oxide.
This interdisciplinary study confirms predictions made by Wentzcovitch and group members in 2014 that lateral temperature variations in the lower mantle produce an anti-correlation between bulk and shear velocities owing to the spin crossover in iron in ferropericlase. This effect provides an interpretation for previously mysterious observations in seismic tomography maps.
Shephard, G.E., Houser, C.,et al., Wentzcovitch, R.M., Seismological expression of the iron spin crossover in ferropericlase in the Earth’s lower mantle. Nat Commun 12, 5905 (2021). https://doi.org/10.1038/s41467-021-26115-z
Researchers have identified a quantum phase transition taking place in iron more than 1000 kilometres deep within the Earth’s mantle. This transition, known as a spin crossover, also occurs in nanomaterials used for recording information magnetically, meaning that the effect stretches from the macro- to the nanoscale.
Cold, subducting oceanic plates are seen as fast velocity regions in (a) and (b), and warm rising mantle rock is seen as slow velocity regions in (c). Plates and plumes produce a coherent tomographic signal in S-wave models, but the signal partially disappears in P-wave models. (Courtesy: Columbia Engineering)
In 2006, Columbia Engineering Professor Renata Wentzcovitch published her first paper on ferropericlase, providing a theory for the spin crossover in this mineral. Her theory suggested it happened across a thousand kilometers in the lower mantle. Since then, Wentzcovitch, who is a professor in the applied physics and applied mathematics department, earth and environmental sciences, and Lamont-Doherty Earth Observatory at Columbia University, has published 13 papers with her group on this topic, investigating velocities in every possible situation of the spin crossover in ferropericlase and bridgmanite, and predicting properties of these minerals throughout this crossover. In 2014, Wenzcovitch, whose research focuses on computational quantum mechanical studies of materials at extreme conditions, in particular planetary materials predicted how this spin change phenomenon could be detected in seismic tomographic images, but seismologists still could not see it.
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Working with a multidisciplinary team from Columbia Engineering, the University of Oslo, the Tokyo Institute of Technology, and Intel Co., Wenzcovitch’s latest paper details how they have now identified the ferropericlase spin crossover signal, a quantum phase transition deep within the Earth’s lower mantle. This was achieved by looking at specific regions in the Earth’s mantle where ferropericlase is expected to be abundant. The study was published October 8, 2021, in Nature Communications.
“This exciting finding, which confirms my earlier predictions, illustrates the importance of materials physicists and geophysicists working together to learn more about what’s going on deep within the Earth,” said Wentzcovitch.
Spin transition is commonly used in materials like those used for magnetic recording. If you stretch or compress just a few nanometer-thick layers of a magnetic material, you can change the layer's magnetic properties and improve the medium recording properties. Wentzcovitch’s new study shows that the same phenomenon happens across thousands of kilometers in the Earth’s interior, taking this from the nano- to the macro-scale.
“Moreover, geodynamic simulations have shown that the spin crossover invigorates convection in the Earth’s mantle and tectonic plate motion. So we think that this quantum phenomenon also increases the frequency of tectonic events such as earthquakes and volcanic eruptions,” Wentzcovitch notes.
Our planet is full of mysteries. How exactly did Earth form and evolve to its current state? Why do some places in its interior seem hotter or colder, rising or sinking? For answers, geoscientists experiment on materials expected to be found in Earth’s interior, but these exist at immense pressures and temperatures that are impractical to reproduce in the lab. Renata Wentzcovitch, a condensed matter physicist, says quantum simulations can help.
“Nature is quantum,” said Wentzcovitch, a professor at Columbia Engineering and the Lamont Doherty Earth Observatory.
Ferropericlase, one of the primary mantle minerals, is known to have an electronic spin transition. However, evidence of this transition in the Earth’s mantle has been challenging to find. Shephard et al. found changes in seismic wave speeds at two depth ranges that correspond to the iron spin transition in ferropericlase. The authors compared compressional and sheer-wave velocities in tomographic models, finding relative changes between the two types of waves that they could attribute to the transition. Using tomographic models is important because nonuniform thermochemical variations wash the signal out in global, one-dimensional models.
Nat. Commun. 12, 5905 (2021).