机构地区:[1]Department of Geophysics,Stanford University
出 处:《Chinese Science Bulletin》2011年第13期1292-1317,共26页
基 金:support from the US National Science Foundation grants NSF EAR-0406658 and EAR-0909319;funded under the American Recovery and Reinvestment Act of 2009 (ARRA) (Public Law111-5)
摘 要:Small-scale convection supplies heat flow of ~17 mW m-2 to the base of stable continents where xenolith studies resolve the geotherm.However,effects of small-scale convection are difficult to resolve in ocean basins.On first pass,most seafloor appears to subside to an asymptote compatible with ~40 mW m-2 convective heat flow.These common regions are tracked by hotspots so uplift associated with ponded mantle material is an attractive alternative.Unaffected seafloor in the North and South Atlantic continues to subside with the square root of age as expected from pure conduction.The theory of stagnant-lid convection provides good scaling relationships for heat flow.For linear viscosity,heat flow is proportional to the underlying "half-space" viscosity to the 1/3 power and the temperature to change viscosity by a factor of e to the 4/3 power.The formalism is easily modified to represent convection beneath a lid of highly viscous and buoyant cratonal lithosphere and to represent transient convection beneath thickening oceanic lithosphere.Asthenospheric mantle with linear,strongly temperature-dependent,and weakly depth-dependent viscosity is compatible with both oceanic and continental data.More complicated rheology may allow vigorous small-scale convection under most but not all old ocean basins.Still viable hypotheses require poorly understood global features,including lateral variations of asthenospheric temperature.Seismological studies have the potential to resolve the lithosphere-asthenosphere boundary,including local variations of its depth associated with small-scale convection.Small-scale convection supplies heat flow of -17 mW m^-2 to the base of stable continents where xenolith studies resolve the geotherm. However, effects of small-scale convection are difficult to resolve in ocean basins. On first pass, most seafloor appears to subside to an asymptote compatible with -40 mW m^-2 convective heat flow. These common regions are tracked by hotspots so uplift associated with ponded mantle material is an attractive alternative. Unaffected seafloor in the North and South Atlantic continues to subside with the square root of age as expected from pure conduction. The theory of stagnant-lid convection provides good scaling relationships for heat flow. For linear viscosity, heat flow is proportional to the underlying "half-space" viscosity to the -1/3 power and the temperature to change viscosity by a factor of e to the 4/3 power. The formalism is easily modified to represent convection beneath a lid of highly viscous and buoyant cratonal lithosphere and to represent transient convection beneath thickening oceanic lithosphere. Asthenospheric mantle with linear, strongly temperature-dependent, and weakly depth-dependent viscosity is compatible with both oceanic and continental data. More complicated rheology may allow vigorous small-scale con- vection under most but not all old ocean basins. Still viable hypotheses require poorly understood global features, including lateral variations of asthenospheric temperature. Seismological studies have the potential to resolve the lithosphere-asthenosphere boundary, including local variations of its depth associated with small-scale convection.
关 键 词:小尺度对流 大陆 大洋岩石圈 海洋 大洋盆地 地幔物质 温度改变 数据兼容
分 类 号:P314[天文地球—固体地球物理学]
正在载入数据...
正在载入数据...
正在载入数据...
正在载入数据...
正在载入数据...
正在载入数据...
正在载入数据...
