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- Title
Mesoscale atmospheric circulation controls of local meteorological elevation gradients on Kersten Glacier near Kilimanjaro summit.
- Authors
Mölg, Thomas; Hardy, Douglas R.; Collier, Emily; Kropač, Elena; Schmid, Christina; Cullen, Nicolas J.; Kaser, Georg; Prinz, Rainer; Winkler, Michael
- Abstract
Elevation gradients of meteorological variables in mountains are of interest to a number of scientific disciplines and often required as parameters in modeling frameworks. Measurements of such gradients on glaciers, however, are particularly scarce and strongly skewed towards the mid latitudes and valley glaciers. This article adds a tropical perspective and presents four years of overlapping measurements at 5603 m and 5873 m on Kersten Glacier, Kilimanjaro (East Africa), between 2009 and 2013. Mean gradients in near-surface air temperature (T), water vapor pressure (VP) and snow accumulation (ACC) per 100 m elevation are -0.75 °C, -0.16 hPa and -114 ± 16 mm w.e. per year, respectively. An intriguing feature is a strong diurnal cycle of theT and VP gradients, which are (depending on season) 2-4 times larger between early and late morning than in the hours of weak gradients. The ACC decrease with elevation, furthermore, is mostly the result of a lower frequency of ACC events at the upper measurement site and not due to contrasting amounts at the two altitudes during events. A novel facet of our study is to link the measured on-glacier gradients to a high-resolution atmospheric modeling data set, which reveals the importance of the mesoscale atmospheric circulation. A thermally direct circulation is established over the mountain in response to diabatic surface heating/cooling with upslope flow during the day and downslope flow in the night. This persistent circulation communicates heat and moisture changes in the lowlands to the higher elevations during morning and early afternoon, which is evident in the advection patterns of potential temperature and VP, and shapes the time-variability of gradients as recorded by our weather stations on the glacier. A few local processes seem to matter as well (glacier sublimation, turbulent heat fluxes), yet they show a secondary influence only during limited time windows. Atmospheric model data also demonstrate that declining moist entropy and water vapor fluxes in the summit zone favor formation of the negative ACC gradient. The results extend the empirical basis of elevation gradients in high mountains, and in particular over glacier surfaces, by the unusual case of a slope glacier on an equatorial, free-standing massif. Our measurement/model link, moreover, demonstrates an approach for future studies to put observations of elevation gradients more systematically in a multiscale process context.
- Subjects
KILIMANJARO, Mount (Tanzania); ATMOSPHERIC circulation; WATER vapor transport; GLACIERS; ALTITUDES; WATER vapor; GLACIOLOGY
- Publication
Earth System Dynamics Discussions, 2019, p1
- ISSN
2190-4995
- Publication type
Article
- DOI
10.5194/esd-2019-51