Water Vapor and Lapse Rate Feedbacks

Water Vapor and Lapse Rate Feedbacks Neil Gordon ESP Seminar April 14, 2006

Climate Change – Feedback Mechanisms • Feedback: A sequence of interactions that determines the response of a system to an initial perturbation • source: AMS Glossary • Some major climate feedbacks relating to climate: • Ice-Albedo (positive feedback) • Higher surface temperatures  Less ice and snow cover • Lower albedo  More surface absorption  higher surface temperatures • Water Vapor (positive feedback) • More GHGs  Higher surface temperatures  More evaporation •  More water vapor = More GHGs • Clouds (net negative feedback) • Higher surface temperatures  More evaporation  Higher specific humidity •  More clouds  Higher albedo  Lower surface temperatures •  More longwave absorption  Higher surface temperatures

Structure of the Troposphere • Temperature decays with height at a rate of ~6-7 K/km over the troposphere (lowest 10-12 km of the atmosphere) • Water vapor is mostly concentrated in the lowest 1.5 km of the troposphere

Temperature Profile from http://www.atmosphere.mpg.de/media/archive/

More Detail on GHG Forcing • We can think of the surface atmosphere system radiating as a whole to space • The top-of-atmopshere (TOA) incoming radiation is primarily constant but how the Earth balances that is not • As GHG concentrations increase in the atmosphere, the effective height of emission increases, thus reducing the outgoing longwave radiation (OLR) • So, more radiation is entering the climate system and the surface and atmosphere have to warm to compensate

Climate Energy Balance

from Soden and Held (2000)

Lapse Rate Feedback • The rate of temperature decay with height, or the slope of the temperature profile (lapse rate), is controlled by radiation, large-scale dynamics and convection • If the lapse rate were to decrease, then the temperature of the effective level of emission would warm (negative feedback) • This is a proposed negative feedback in the tropics, but it is thought to be relatively small (Zhang et al, 1994)

Water Vapor Feedback • As atmospheric temperature increases, the ability of that air to hold more water vapor increases • So, if relative humidity is held constant as temperature increases, the total moisture in the air increases • Water vapor is opaque to IR radiation, making it a greenhouse gas

Relative Humidity (350-500mb) from Lindzen et al. (2001)

Water Vapor Feedback • The increase in total moisture in the lower troposphere as temperature increases is well-observed (Wentz and Schabel, 2000) • In order for water vapor to change the radiation balance, it must increase in the free troposphere • So, to change the free tropospheric water vapor, there must be a mehcanism to transport the water aloft • Held and Soden (2000) found that for fixed RH, the total water vapour feedback contributed by increases in WV below 850mb was only 10% of the total response

Mt. Pinatubo Experiment • Soden et al. (2002) used the global cooling (and drying) resulting from the eruption of Mt. Pinatubo to test the water vapor feedback hypothesis • Global climate models were only able to reproduce the observed cooling if the water vapor feedback was included

Adaptive Iris Hypothesis • Lindzen et al. (2001) propose a mechanism whereby increased surface temperature leads to more vigorous tropical convection • The enhanced convection increases the ability of the cloud to precipitate • The total water then transported to the upper atmosphere is reduced

Tropical Convection from http://www.divinewindbook.com/figures/images/

Water Vapor and Lapse Rate Feedbacks