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Geology, mineralogy, petrology, perovskites

Professor of Earth Materials

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Appointment:	Room:
Professor of Earth Materials	Kathleen Lonsdale, G13
Courses Taught:
GEOL0039ÌýEarth and Planetary System Science
GEOL0023 Crustal Dynamics and Mountain Building
Research Group(s):
Crystallography and Mineral Physics
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Email Address:	Telephone Number:
d.dobson@ucl.ac.uk	020 3108 6335 (56335)

Research Summary

long with colleagues at ÐÂÏã¸ÛÁùºÏ²Ê¿ª½±½á¹ûand theÌýBayerisches Geoinstitut, I perform high-pressure experiments on deep Earth minerals and rocks. We have several high-pressure devices, including multi-anvil presses, Diamond cells and a modified Paris-Edinburgh cell for neutron diffraction.

The core of the Earth is among the most inaccessible and least understood regions of Earth. The solid inner core and liquid outer core consist of iron plus several percent of a light element. Together with DrÌýIan WoodÌýand ProfÌýLidunka Vocadlo, I have been investigating the iron-alloys which are stable at high pressures. We have discovered a new high-pressure phase of FeSi which is a prime core candidate material.

Research Interest

Along with colleagues at ÐÂÏã¸ÛÁùºÏ²Ê¿ª½±½á¹ûand theÌý, I perform high-pressure experiments on deep Earth minerals and rocks. We have several high-pressure devices, including multi-anvil presses, Diamond cells and a modified Paris-Edinburgh cell for neutron diffraction.

Earth's Core Materials

Ian Wood and Lidunka Vocadlo, I have been investigating the iron-alloys which are stable at high pressures. We have discovered a new high-pressure phase of FeSi which is a prime core candidate material.

The outer core is responsible for the Earth’s magnetic field. Geodynamo models require a knowledge of the viscosity and diffusivity of the outer core liquid. We have an active programme to measure these properties at high pressure.Ìý

Transport Properties of Mantle Materials

Prof John BrodholtÌýand I been investigating the electrical conductivity of mantle minerals olivine, wadsleyite, magnesiowustite and perovskite. We have used these results to test whether the mantle convects in a layered or whole-mantle fashion.

The viscosity of the mantle is very poorly constrained. In the Laboratory forÌý, we have a programme to develop new rheological testing apparatus for ultra-high-pressure experiments. These include the Gigapascal Deformation Cell and the modified Paris-Edinburgh-Belt cell. We will use Neutron diffraction to measure deviatoric stresses and strains in situ at the new ENGIN-X beamline at Rutherford Appleton Laboratory.

Along withÌýProf. Phil MeredithÌýandÌýSteve BoonÌýwe are developing new techniques to investigate the origins of deep earthquakes. Our recent work on serpentine dehydration was published in Science and featured in the international press. See what the BBC has to say aboutÌýÌýandÌý.

True colour images of partially dehydrated serpentine recovered from 6 GPa (top) and 8 GPa (bottom).

The strikingly different colours are due to the different dehydration reactions at the two pressures:

Serpentine = olivine + enstatite + water (6 GPa) and:

serpentine = phase A + enatatite + water (8GPa).

Both samples showed seismic signals during dehydration, but the type of signal was significantly different.

The outer core is responsible for the Earth’s magnetic field. Geodynamo models require a knowledge of the viscosity and diffusivity of the outer core liquid. We have an active programme to measure these properties at high pressure.

High-pressure experiments on deep Earth materials; synthesis and properties of new Fe-alloy phases relevant to the core; transport properties of mantle mineral rocks and minerals; deep seismicity.