Add to ORKGThe compositional evolution of volcanic bodies like Io is not well understood. Magmatic segregation and volcanic eruptions transport tidal heat from Io's interior to its surface. Several observed eruptions appear to be extremely high temperature (≥1600 K), suggesting either very high degrees of melting, refractory source regions, or intensive viscous heating on ascent. To address this ambiguity, we develop a model that couples crust and mantle dynamics to a simple compositional system. We analyze the model to investigate chemical structure and evolution. We demonstrate that magmatic segregation and volcanic eruptions lead to stratification of the mantle, the extent of which depends on how easily high temperature melts from the more refracto...
Io has very high surface heat flow and an abundance of volcanic activity, which are thought to be dr...
Io's surface is younger and has more active volcanism than any other terrestrial body in the solar s...
Topographic features on Io tend to subside because their underlying roots are softened and eroded by...
Global volcanism has implications for planetary evolution far beyond the surface features that we ob...
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....
We model the density structure of the outer several tens of kilometers of Io on the basis of the ass...
Io is currently emitting 1–1.5 W m−2 of tidal energy as a result of its volcanic activity. If the li...
The silicate "magma trigger" model of volcanism on Io has been evaluated numerically with finite ele...
Over the last fifty years, our knowledge of the Solar System has increased exponentially. Many plane...
The chemistry of magmas erupted by volcanoes is a message from deep within the Earth's crust, which ...
Rocky planetesimals in the early solar system melted internally and evolved chemically due to radiog...
Satellite and recent Earth-based observations of Io's surface reveal a specific spatial pattern of p...
Tidal heating is expected to impart significant, non-spherically-symmetric structure to Jupiter’s vo...
Data accompanying the publication Steinke et al. 2020 - "Can a combination of convective and magmati...
Io has very high surface heat flow and an abundance of volcanic activity, which are thought to be dr...
Io's surface is younger and has more active volcanism than any other terrestrial body in the solar s...
Topographic features on Io tend to subside because their underlying roots are softened and eroded by...
Global volcanism has implications for planetary evolution far beyond the surface features that we ob...
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....
We model the density structure of the outer several tens of kilometers of Io on the basis of the ass...
Io is currently emitting 1–1.5 W m−2 of tidal energy as a result of its volcanic activity. If the li...
The silicate "magma trigger" model of volcanism on Io has been evaluated numerically with finite ele...
Over the last fifty years, our knowledge of the Solar System has increased exponentially. Many plane...
The chemistry of magmas erupted by volcanoes is a message from deep within the Earth's crust, which ...
Rocky planetesimals in the early solar system melted internally and evolved chemically due to radiog...
Satellite and recent Earth-based observations of Io's surface reveal a specific spatial pattern of p...
Tidal heating is expected to impart significant, non-spherically-symmetric structure to Jupiter’s vo...
Data accompanying the publication Steinke et al. 2020 - "Can a combination of convective and magmati...
Io has very high surface heat flow and an abundance of volcanic activity, which are thought to be dr...
Io's surface is younger and has more active volcanism than any other terrestrial body in the solar s...
Topographic features on Io tend to subside because their underlying roots are softened and eroded by...