Solar system

Explosive volcanic activity on Venus: The roles of volatile contribution, degassing, and external environment

Planetary and Space Science Elsevier 113 (2015) 33-48

Authors:

MW Airey, TA Mather, DM Pyle, LS Glaze, RC Ghail, CF Wilson

Introduction to the special issue on Venus exploration

Planetary and Space Science Elsevier 113 (2015) 1

Authors:

H Svedhem, C Wilson, G Piccioni

The CO2 continuum absorption in the 1.10- and 1.18-μm windows on Venus from Maxwell Montes transits by SPICAV IR onboard Venus express

Planetary and Space Science Elsevier 113 (2015) 66-77

Authors:

Anna Fedorova, Bruno Bézard, Jean-Loup Bertaux, Oleg Korablev, Colin Wilson

Modeling gravitational instabilities in self-gravitating protoplanetary disks with adaptive mesh refinement techniques

Astronomy & Astrophysics EDP Sciences 579 (2015) a32

Authors:

Tim Lichtenberg, Dominik RG Schleicher

Feedback temperature dependence determines the risk of high warming

Geophysical Research Letters Wiley 42:12 (2015) 4973-4980

Authors:

Jonah Bloch-Johnson, Raymond T Pierrehumbert, Dorian S Abbot

Abstract:

The long-term warming from an anthropogenic increase in atmospheric CO2 is often assumed to be proportional to the forcing associated with that increase. This paper examines this linear approximation using a zero-dimensional energy balance model with a temperature-dependent feedback, with parameter values drawn from physical arguments and general circulation models. For a positive feedback temperature dependence, warming increases Earth's sensitivity, while greater sensitivity makes Earth warm more. These effects can feed on each other, greatly amplifying warming. As a result, for reasonable values of feedback temperature dependence and preindustrial feedback, Earth can jump to a warmer state under only one or two CO2 doublings. The linear approximation breaks down in the long tail of high climate sensitivity commonly seen in observational studies. Understanding feedback temperature dependence is therefore essential for inferring the risk of high warming from modern observations. Studies that assume linearity likely underestimate the risk of high warming.