Three dimensional models of Martian mantle convection with phase transitions

We have employed a three-dimensional compressible convection model to study the dynamics of phase transitions in the Martian mantle. A large core model with two exothermic phase transitions, the olivine to β-spinel and the β- to γ-spinel transition, and a small core model including also the endothermic spinel to perovskite transition have been considered. The two exothermic transitions create ‘thermal barriers’ for small upwellings due to the latent heat consumption from the phase change. Upwelling plumes lose part or all of their buoyancy, which causes the formation of one stable area full of plumes. This tendency for the merging of plumes increases with internal heating. This type of convective planform is consistent with the relatively few large volcanic centers. The presence of a 175 km thick perovskite layer above the core-mantle boundary (CMB) yields a similar flow pattern, albeit with an even smaller number of plumes. However, the excess temperatures of the plumes and the mantle flow velocities in the lower mantle are smaller than those found in models without perovskite layer. The phase transitions cause an increase of temperature near the CMB, which prevents the lower mantle and the core from extensive cooling. A model with a perovskite layer decreasing in thickness with time can account for a peak in volcanic and magnetic activity early in the Martian history.

[1]  N. Phillips,et al.  Scale Analysis of Deep and Shallow Convection in the Atmosphere , 1962 .

[2]  S. Weinstein The effects of a deep mantle endothermic phase change on the structure of thermal convection in silicate planets , 1995 .

[3]  H. Harder Phase transitions and the three‐dimensional planform of thermal convection in the Martian mantle , 1998 .

[4]  D. Yuen,et al.  Layered convection induced by phase transitions , 1985 .

[5]  D. Yuen,et al.  Phase transitions in the Martian mantle and the generation of megaplumes , 1995 .

[6]  S. Young,et al.  ERUPTION OF SOUFRIERE HILLS VOLCANO IN MONTSERRAT CONTINUES , 1997 .

[7]  Ronald Greeley,et al.  Volcanism on Mars , 1981 .

[8]  Ulrich R. Christensen,et al.  A one-plume model of martian mantle convection , 1996, Nature.

[9]  D. Yuen,et al.  Phase transitions in the Martian mantle: Implications for the planet's volcanic history , 1996 .

[10]  Tilman Spohn,et al.  Thermal history of Mars and the sulfur content of its core , 1990 .

[11]  T. Spohn,et al.  Mantle differentiation and the crustal dichotomy of Mars , 1993 .

[12]  T. Spohn,et al.  Mars: a magnetic field due to thermoremanence? , 1997 .

[13]  Tilman Spohn,et al.  The interior structure of Mars: Implications from SNC meteorites , 1997 .

[14]  David A. Yuen,et al.  Various influences on plumes and dynamics in time-dependent, compressible mantle convection in 3-D spherical shell , 1996 .

[15]  N. Barlow,et al.  The Martian impact cratering record. , 1992 .

[16]  T. Spohn Mantle differentiation and thermal evolution of Mars, Mercury, and Venus , 1991 .

[17]  Ronald Greeley,et al.  The resurfacing history of Mars - A synthesis of digitized, viking-based geology , 1988 .

[18]  Ulrich R. Christensen,et al.  Some effects of lateral viscosity variations on geoid and surface velocities induced by density anomalies in the mantle , 1993 .

[19]  D. Yuen,et al.  Phase transitions in the Martian mantle: Implications for partially layered convection , 1997 .