Land–atmosphere interactions in the tropics – a review

The continental tropics play a leading role in the terrestrial energy, water, and carbon cycles. Land–atmosphere interactions are integral in the regulation of these fluxes across multiple spatial and temporal scales over tropical continents. We review here some of the important characteristics of tropical continental climates and how land–atmosphere interactions regulate them. Along with a wide range of climates, the tropics manifest a diverse array of land–atmosphere interactions. Broadly speaking, in tropical rainforest climates, light and energy are typically more limiting than precipitation and water supply for photosynthesis and evapotranspiration (ET), whereas in savanna and semi-arid climates, water is the critical regulator of surface fluxes and land–atmosphere interactions. We discuss the impact of the land surface, how it affects shallow and deep clouds, and how these clouds in turn can feed back to the surface by modulating surface radiation and precipitation. Some results from recent research suggest that shallow clouds may be especially critical to land–atmosphere interactions. On the other hand, the impact of land-surface conditions on deep convection appears to occur over larger, nonlocal scales and may be a more relevant land–atmosphere feedback mechanism in transitional dry-to-wet regions and climate regimes.<br/

The Chilean Coastal Orographic Precipitation Experiment: Observing the influence of microphysical rain regimes on coastal orographic precipitation

The Chilean Coastal Orographic Precipitation Experiment (CCOPE) was conducted during the australwinter of 2015 (May–August) in the Nahuelbuta Mountains (peak elevation 1.3 km MSL) of southern Chile(388S). CCOPE used soundings, two profiling Micro Rain Radars, a Parsivel disdrometer, and a rain gaugenetwork to characterize warm and ice-initiated rain regimes and explore their consequences for orographicprecipitation. Thirty-three percent of foothill rainfall fell during warm rain periods, while 50% of rainfall fellduring ice-initiated periods. Warm rain drop size distributions were characterized by many more and relativelysmaller drops than ice-initiated drop size distributions. Both the portion and properties of warm and ice-initiated rainfall compare favorably with observations of coastal mountain rainfall at a similar latitude inCalifornia. Orographic enhancement is consistently strong for rain of both types, suggesting that seeding fromice aloft is not a requisite for large orographic enhancement. While the data suggest that orographic en-hancement may be greater during warm rain regimes, the difference in orographic enhancement betweenregimes is not significant. Sounding launches indicate that differences in orographic enhancement are not easilyexplainable by differences in low-level moisture flux or nondimensional mountain height between the regimes