Erik H. Hauri
Staff Scientist (1994 - 2018)

Eric H. Hauri

Research Interests

Isotopic and chemical evolution of the Earth's deep interior; modeling of flow and melting in mantle plumes; high-pressure experimental petrology; secondary ion mass spectrometry


B.S., University of Miami, 1988 Ph.D., Geochemistry, Massachusetts Institute of Technology and Woods Hole Oceanographic Institution, 1992

Contact & Links

  • (202) 478-8471 | fax: (202) 478-8821
  • ehauri at
  • Earth and Planets Laboratory
    Carnegie Institution for Science
    5241 Broad Branch Road, NW
    Washington, DC 20015-1305
  • Curriculum Vitae
  • Publications
  • Personal Website


The goal of Erik Hauri's research is to understand how planetary processes affect the chemistry of the Earth, Moon and other objects, and to use that chemistry to understand the origin and evolution of planetary bodies.

The minerals that are stable in planetary interiors determine how major elements (silicon, magnesium, iron, calcium, aluminum, titanium, sodium and sometimes water) are distributed, and how they behave when melting occurs and magmas are generated and transported to the surface in volcanoes. The presence of volatiles (water, carbon and others) have a large influence on the strength and melting point of planetary interiors, determining where magmas will be produced, where volcanoes form and how they erupt. Magma generation, and on the Earth the subduction of tectonic plates, produce variability of trace elements in deep planetary interiors. Over time, the accumulation of isotopes produced by radioactive decay (Rb-Sr, Sm-Nd, U-Th-Pb-He, Lu-Hf, Re-Os and others) generate irreversible isotope fingerprints for deep reservoirs, but the constant motion of planetary convection attempts to mix and homogenize this variability.

All of these processes are reflected in the chemistry of deep samples - xenoliths, lavas, volcanic glass, minerals, gases and melt inclusions - that are delivered to the surface by volcanic activity. Where samples are inaccessible, he relies on high-pressure experiments to simulate deep planetary processes - and when conditions are too extreme for the laboratory, we depend on accurate numerical geodynamic models to illuminate the physics of planetary interiors and how they affect the geochemistry.