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Soil carbon substrates affect how methane and CO2 emissions from global wetlands change in response to climate warming, according to global analyses of temperature sensitivity of wetland carbon emissions.
An integrated model of mineral weathering and carbon cycling reveals the substantial influence that clay minerals originating from the weathering of magnesium-rich rocks have on Earth’s climate. This research indicates that this clay-forming process contributed to each Palaeozoic glaciation.
The atmosphere has dried across most regions of Europe in recent decades, a trend that can be attributed primarily to human impacts, according to tree ring records spanning 400 years and Earth system model simulations.
Megathrust earthquakes along subduction zones present significant hazards. Evidence from the South Chile subduction zone suggests that the structure and fluid distribution of the megathrust interface governs the size and timing of large earthquakes.
Geological structure and pore fluid pressure in the subduction zone forearc govern the size and recurrence of megathrust earthquakes in Chile, according to quasi-dynamic simulations of the seismic cycle.
Hydrothermal venting makes limited contribution to the inventory of oceanic mercury compared with anthropogenic inputs, according to measurements at mid-ocean ridges.
Human exploration of the Solar System began on the Moon during the space race of the mid-twentieth century. To facilitate documentation and study of the human influence on the Moon, we argue it is time to designate a ‘Lunar Anthropocene’.
While it may feel cold to the touch, Sheng Fan and David Prior explain that ice on Earth is relatively hot. Understanding ‘hot’ ice physics during deformation is critical in determining future sea-level rise.
Methane dissociated from the base of the hydrate stability zone off Mauritania during warm interglacials travelled up to 40 km landward beyond where methane hydrates are typically found before venting out, according to 3D seismic imagery.
Marine microfossil assemblages refine sea surface temperature patterns and yield insights into discrepancies between paleoclimate models of the last ice age and observations.
Spatial changes in planktonic foraminifera species assemblages reveal steeper thermal gradients in the North Atlantic Ocean during the Last Glacial Maximum than simulated by climate models, according to a macroecological analysis of marine sediment cores.
Three decades of meteorological observations show that Himalayan glaciers have been cooling because of intensified downslope winds, in contrast to the warming observed elsewhere in the region.
Spatially distinct ice-sheet growth on the Antarctic Peninsula through the Pleistocene was the result of dynamic topography and pre-glacial landscape evolution, not climate, according to a palaeotopographic reconstruction and ice-sheet modelling.
High-elevation meteorological observations and reanalysis data indicate local cooling and drying near Himalayan glaciers due to enhanced katabatic winds in response to global warming.
Plant diversity stabilizes grassland soil temperature by boosting soil organic carbon and increasing plant leaf area, according to an 18-year plant diversity experiment.