The stability and transport of carbon dioxide on Iapetus

Carbon dioxide has been detected associated with Iapetus' dark material by the Cassini spacecraft. This CO₂ may be primordial and/or resulting from ongoing production by photolysis of water-ice in the presence of carbonaceous material [Allamandola, L.J., Sandford, S.A., Valero, G.J., 1988. Icarus 76, 225-252]. Although any primordial CO₂ would likely be complexed with the dark material and thus stable against thermal transport to Iapetus' poles [Buratti, B.J., and 28 colleagues, 2005. Astrophys. J. 622, L149-L152], active production of CO₂ would result in some fraction of the CO₂ being mobile enough to allow the accumulation of CO₂ at Iapetus' poles. We develop a computer model to simulate ballistic transport of CO₂ ice on Iapetus, accounting for Iapetus' gravitational binding energy and polar cold traps. We find that the residence time of CO₂ ice outside the polar regions is very short; a sheet of CO₂ ice near the equator of Iapetus decreases in thickness at a rate of 50 mm year⁻¹. The sublimated CO₂ will ballistically move around Iapetus until it reaches the polar cold traps where it can be sequestered for up to 15 years. If the total surface inventory of CO₂ exceeds 3×¹⁰⁷ kg, the polar ice cap will be permanent. While CO₂ is moving around the surface, a small percentage will eventually reach escape velocity and be lost from the system. As such, a seasonal polar cap is lost at rate of 12% every solar orbit as the CO₂ moves between the two polar cold traps.     

土卫八新运动理论的比较研究

通过归算土卫八轨道根数200年的变化将一个最新的高精度土卫运动理论TASS与经典理论作比较,并用20年现代照相观测资料作理论预报精度的归算．归算表明,在一定时期内TASS与经典理论有较好的一致,但其根数长期变化的差很快变大．由此指出,TASS的合理性和进入实用还有待对更长时期大量高精度观测作实算．     

The seismic signature of the Iapetus Suture beneath the North Sea

Summary Deep seismic reflection profiles across the Mid-North Sea High and the Anglo-Dutch basin record a number of intra-crustal and mantle events. When combined with interpretations of potential field data and surface geology, these can be attributed to the Iapetus Suture, beneath the Mid-North Sea High, and the remains of an Ordovician subduction zone, beneath the concealed Caledonide basement of eastern England.     

Magnetic crustal character in Central Ireland

The simplest magnetic model for the upper 20 km of crust in central Ireland is of two layers. A thin, weakly magnetic upper layer carrying a number of magnetic bodies that can be related to surface geology overlies a magnetic crustal zone whose gross magnetization increases towards the north. The deeper trace of the lapetus Suture in central Ireland forms the boundary between a more magnetic northern crustal area and a less magnetic southern area. A pre-Carboniferous major dextral offset of this suture boundary occurs in the Limerick area. The suture is traced beneath the Dingle peninsula in the far south-west of Ireland. In east-central Ireland, between the Iapetus Suture and Southern Upland Line, the crust contains a large, south-dipping magnetic body with no surface expression, which produces the Virginia magnetic anomaly. The development of magnetic bodies — in particular, volcanic rocks of Carboniferous age — has been controlled by regional stress patterns. The major volcanic centre at Limerick lies at the intersection of two major Caledonian block fault systems just to the north of the surface trace of the Hercynian Front.