Add to ORKGThe silicate "magma trigger" model of volcanism on Io has been evaluated numerically with finite element methods by considering the one-dimensional heat transfer between hot silicate magma and initially cold sulfur. It is found that for the probable range of initial magma temperatures and sulfur temperatures, the contact between silicate magma and a sulfur crust will be 700 (+OR-) 100 K, or approximately the vapor point of elemental sulfur. A silicate magma sill or laccolith on the order of 10 m thick will yield energetic vapor for a period of several weeks to several months depending on the vapor temperature and the amount of convective cooling of the silicate magma that occurs at the silicate-sulfur interface. This model may account for t...
In order to provide new insights into the relationship between plutonism and volcanism, numerical si...
Tidal heating is expected to impart significant, non-spherically-symmetric structure to Jupiter’s vo...
To determine how active volcanism might affect the standard picture of sulfur dioxide photochemistry...
The return of the first Voyager images of Io in 1979 provoked a controversy over the importance of ...
Io is currently emitting 1–1.5 W m−2 of tidal energy as a result of its volcanic activity. If the li...
Io's surface is younger and has more active volcanism than any other terrestrial body in the solar s...
Global volcanism has implications for planetary evolution far beyond the surface features that we ob...
We model the density structure of the outer several tens of kilometers of Io on the basis of the ass...
Tidal dissipation makes Jupiter's moon Io the most volcanically active body in the solar system. Mos...
Io, the most volcanically active body in the solar system, loses heat through eruptions of hot lava....
Over the last fifty years, our knowledge of the Solar System has increased exponentially. Many plane...
Io has very high surface heat flow and an abundance of volcanic activity, which are thought to be dr...
The compositional evolution of volcanic bodies like Io is not well understood. Magmatic segregation ...
Satellite and recent Earth-based observations of Io's surface reveal a specific spatial pattern of p...
Jupiter’s moon Io is the most volcanically active body in the solar system. This paper seeks to qu...
In order to provide new insights into the relationship between plutonism and volcanism, numerical si...
Tidal heating is expected to impart significant, non-spherically-symmetric structure to Jupiter’s vo...
To determine how active volcanism might affect the standard picture of sulfur dioxide photochemistry...
The return of the first Voyager images of Io in 1979 provoked a controversy over the importance of ...
Io is currently emitting 1–1.5 W m−2 of tidal energy as a result of its volcanic activity. If the li...
Io's surface is younger and has more active volcanism than any other terrestrial body in the solar s...
Global volcanism has implications for planetary evolution far beyond the surface features that we ob...
We model the density structure of the outer several tens of kilometers of Io on the basis of the ass...
Tidal dissipation makes Jupiter's moon Io the most volcanically active body in the solar system. Mos...
Io, the most volcanically active body in the solar system, loses heat through eruptions of hot lava....
Over the last fifty years, our knowledge of the Solar System has increased exponentially. Many plane...
Io has very high surface heat flow and an abundance of volcanic activity, which are thought to be dr...
The compositional evolution of volcanic bodies like Io is not well understood. Magmatic segregation ...
Satellite and recent Earth-based observations of Io's surface reveal a specific spatial pattern of p...
Jupiter’s moon Io is the most volcanically active body in the solar system. This paper seeks to qu...
In order to provide new insights into the relationship between plutonism and volcanism, numerical si...
Tidal heating is expected to impart significant, non-spherically-symmetric structure to Jupiter’s vo...
To determine how active volcanism might affect the standard picture of sulfur dioxide photochemistry...