45 research outputs found
Changes in zonal surface temperature gradients and Walker circulations in a wide range of climates
Variations in zonal surface temperature gradients and zonally asymmetric
tropical overturning circulations (Walker circulations) are examined over a
wide range of climates simulated with an idealized atmospheric general
circulation model (GCM). The asymmetry in the tropical climate is generated by
an imposed ocean energy flux, which does not vary with climate. The range of
climates is simulated by modifying the optical thickness of an idealized
longwave absorber (representing greenhouse gases).
The zonal surface temperature gradient in low latitudes generally decreases
as the climate warms in the idealized GCM simulations. A scaling relationship
based on a two-term balance in the surface energy budget accounts for the
changes in the zonally asymmetric component of the GCM-simulated surface
temperature gradients.
The Walker circulation weakens as the climate warms in the idealized
simulations, as it does in comprehensive simulations of climate change. The
wide range of climates allows a systematic test of energetic arguments that
have been proposed to account for these changes in the tropical circulation.
The analysis shows that a scaling estimate based on changes in the hydrological
cycle (precipitation rate and saturation specific humidity) accounts for the
simulated changes in the Walker circulation. However, it must be evaluated
locally, with local precipitation rates. If global-mean quantities are used,
the scaling estimate does not generally account for changes in the Walker
circulation, and the extent to which it does is the result of compensating
errors in changes in precipitation and saturation specific humidity that enter
the scaling estimate
Atmospheric Circulation of Terrestrial Exoplanets
The investigation of planets around other stars began with the study of gas
giants, but is now extending to the discovery and characterization of
super-Earths and terrestrial planets. Motivated by this observational tide, we
survey the basic dynamical principles governing the atmospheric circulation of
terrestrial exoplanets, and discuss the interaction of their circulation with
the hydrological cycle and global-scale climate feedbacks. Terrestrial
exoplanets occupy a wide range of physical and dynamical conditions, only a
small fraction of which have yet been explored in detail. Our approach is to
lay out the fundamental dynamical principles governing the atmospheric
circulation on terrestrial planets--broadly defined--and show how they can
provide a foundation for understanding the atmospheric behavior of these
worlds. We first survey basic atmospheric dynamics, including the role of
geostrophy, baroclinic instabilities, and jets in the strongly rotating regime
(the "extratropics") and the role of the Hadley circulation, wave adjustment of
the thermal structure, and the tendency toward equatorial superrotation in the
slowly rotating regime (the "tropics"). We then survey key elements of the
hydrological cycle, including the factors that control precipitation, humidity,
and cloudiness. Next, we summarize key mechanisms by which the circulation
affects the global-mean climate, and hence planetary habitability. In
particular, we discuss the runaway greenhouse, transitions to snowball states,
atmospheric collapse, and the links between atmospheric circulation and CO2
weathering rates. We finish by summarizing the key questions and challenges for
this emerging field in the future.Comment: Invited review, in press for the Arizona Space Science Series book
"Comparative Climatology of Terrestrial Planets" (S. Mackwell, M. Bullock,
and J. Harder, editors). 56 pages, 26 figure
Coupled High-Latitude Climate Feedbacks and Their Impact on Atmospheric Heat Transport
The response of atmospheric heat transport to anthropogenic warming is determined by the anomalous meridional energy gradient. Feedback analysis offers a characterization of that gradient and hence reveals how uncertainty in physical processes may translate into uncertainty in the circulation response. However, individual feedbacks do not act in isolation. Anomalies associated with one feedback may be compensated by another, as is the case for the positive water vapor and negative lapse rate feedbacks in the tropics. Here a set of idealized experiments are performed in an aquaplanet model to evaluate the coupling between the surface albedo feedback and other feedbacks, including the impact on atmospheric heat transport. In the tropics, the dynamical response manifests as changes in the intensity and structure of the overturning Hadley circulation. Only half of the range of Hadley cell weakening exhibited in these experiments is found to be attributable to imposed, systematic variations in the surface albedo feedback. Changes in extratropical clouds that accompany the albedo changes explain the remaining spread. The feedback-driven circulation changes are compensated by eddy energy flux changes, which reduce the overall spread among experiments. These findings have implications for the efficiency with which the climate system, including tropical circulation and the hydrological cycle, adjusts to high-latitude feedbacks over climate states that range from perennial or seasonal ice to ice-free conditions in the Arctic
Hadley Circulation Response to Orbital Precession. Part I: Aquaplanets
The response of the monsoonal and annual-mean Hadley circulation to orbital precession is examined in an idealized atmospheric general circulation model with an aquaplanet slab-ocean lower boundary. Contrary to expectations, the simulated monsoonal Hadley circulation is weaker when perihelion occurs at the summer solstice than when aphelion occurs at the summer solstice. The angular momentum balance and energy balance are examined to understand the mechanisms that produce this result. That the summer with stronger insolation has a weaker circulation is the result of an increase in the atmosphere’s energetic stratification, the gross moist stability, which increases more than the amount required to balance the change in atmospheric energy flux divergence necessitated by the change in top-of-atmosphere net radiation. The solstice-season changes result in annual-mean Hadley circulation changes (e.g., changes in circulation strength)
The Tropical Precipitation Response to Orbital Precession
Orbital precession changes the seasonal distribution of insolation at a given latitude but not the annual mean. Hence, the correlation of paleoclimate proxies of annual-mean precipitation with orbital precession implies a nonlinear rectification in the precipitation response to seasonal solar forcing. It has previously been suggested that the relevant nonlinearity is that of the Clausius–Clapeyron relationship. Here it is argued that a different nonlinearity related to moisture advection by the atmospheric circulation is more important. When perihelion changes from one hemisphere’s summer solstice to the other’s in an idealized aquaplanet atmospheric general circulation model, annual-mean precipitation increases in the hemisphere with the brighter, warmer summer and decreases in the other hemisphere, in qualitative agreement with paleoclimate proxies that indicate such hemispherically antisymmetric climate variations. The rectification mechanism that gives rise to the precipitation changes is identified by decomposing the perturbation water vapor budget into “thermodynamic” and “dynamic” components. Thermodynamic changes (caused by changes in humidity with unchanged winds) dominate the hemispherically antisymmetric annual-mean precipitation response to precession in the absence of land–sea contrasts. The nonlinearity that enables the thermodynamic changes to affect annual-mean precipitation is a nonlinearity of moisture advection that arises because precession-induced seasonal humidity changes correlate with the seasonal cycle in low-level convergence. This interpretation is confirmed using simulations in which the Clausius–Clapeyron relationship is explicitly linearized. The thermodynamic mechanism also operates in simulations with an idealized representation of land, although in these simulations the dynamic component of the precipitation changes is also important, adding to the thermodynamic precipitation changes in some latitudes and offsetting it in others
Hadley Circulation Response to Orbital Precession. Part II: Subtropical Continent
The response of the monsoonal and annual-mean Hadley circulation to orbital precession is examined in an idealized atmospheric general circulation model with a simplified representation of land surface processes in subtropical latitudes. When perihelion occurs in the summer of a hemisphere with a subtropical continent, changes in the top-of-atmosphere energy balance, together with a poleward shift of the monsoonal circulation boundary, lead to a strengthening of the monsoonal circulation. Spatial variations in surface heat capacity determine whether radiative perturbations are balanced by energy storage or by atmospheric energy fluxes. Although orbital precession does not affect annual-mean insolation, the annual-mean Hadley circulation does respond to orbital precession because its sensitivity to radiative changes varies over the course of the year: the monsoonal circulation in summer is near the angular momentum-conserving limit and responds directly to radiative changes; whereas in winter, the circulation is affected by the momentum fluxes of extratropical eddies and is less sensitive to radiative changes
Atmospheric gravitational tides of Earth-like planets orbiting low-mass stars
Temperate terrestrial planets orbiting low-mass stars are subject to strong
tidal forces. The effects of gravitational tides on the solid planet and that
of atmospheric thermal tides have been studied, but the direct impact of
gravitational tides on the atmosphere itself has so far been ignored. We first
develop a simplified analytic theory of tides acting on the atmosphere of a
planet. We then implement gravitational tides into a general circulation model
of a static-ocean planet in a short-period orbit around a low-mass star -- the
results agree with our analytic theory. Because atmospheric tides and
solid-body tides share a scaling with the semi-major axis, we show that there
is a maximum amplitude of the atmospheric tide that a terrestrial planet can
experience while still having a solid surface; Proxima Centauri b is the poster
child for a planet that could be geophysically Earth-like but with atmospheric
tides more than 500 stronger than Earth's. In this most extreme
scenario, we show that atmospheric tides significantly impact the planet's
meteorology -- but not its climate. Two possible modest climate impacts are
enhanced longitudinal heat transport and cooling of the lowest atmospheric
layers. The strong radiative forcing of such planets dominates over
gravitational tides, unlike moons of cold giant planets, such as Titan. We
speculate that atmospheric tides could be climatologically important on planets
where the altitude of maximal tidal forcing coincides with the altitude of
cloud formation and that the effect could be detectable for non-Earth-like
planets subject to even greater tides
Coupled High-Latitude Climate Feedbacks and Their Impact on Atmospheric Heat Transport
The response of atmospheric heat transport to anthropogenic warming is determined by the anomalous meridional energy gradient. Feedback analysis offers a characterization of that gradient and hence reveals how uncertainty in physical processes may translate into uncertainty in the circulation response. However, individual feedbacks do not act in isolation. Anomalies associated with one feedback may be compensated by another, as is the case for the positive water vapor and negative lapse rate feedbacks in the tropics. Here a set of idealized experiments are performed in an aquaplanet model to evaluate the coupling between the surface albedo feedback and other feedbacks, including the impact on atmospheric heat transport. In the tropics, the dynamical response manifests as changes in the intensity and structure of the overturning Hadley circulation. Only half of the range of Hadley cell weakening exhibited in these experiments is found to be attributable to imposed, systematic variations in the surface albedo feedback. Changes in extratropical clouds that accompany the albedo changes explain the remaining spread. The feedback-driven circulation changes are compensated by eddy energy flux changes, which reduce the overall spread among experiments. These findings have implications for the efficiency with which the climate system, including tropical circulation and the hydrological cycle, adjusts to high-latitude feedbacks over climate states that range from perennial or seasonal ice to ice-free conditions in the Arctic