Your search keyword '"Renfrew, Ian A."' showing total 2 results

1. Foehn warming distributions in nonlinear and linear flow regimes: a focus on the Antarctic Peninsula.

Author

Elvidge, Andrew D., Renfrew, Ian A., King, John C., Orr, Andrew, and Lachlan‐Cope, Tom A.

Subjects

*FOHN, *GRAVITY waves, *HYDRAULIC jump

Abstract

The structure of lee-side warming during foehn events is investigated as a function of crossbarrier flow regime linearity. Two contrasting cases of westerly flow over the Antarctic Peninsula (AP) are considered -- one highly nonlinear, the other relatively linear.Westerly flow impinging on the AP provides one of the best natural laboratories in the world for the study of foehn, owing to itsmaritime setting and the Larsen C Ice Shelf (LCIS) providing an expansive, homogeneous and smooth surface on its east side. Numerical simulations with the Met Office Unified Model (at 1.5 km grid size) and aircraft observations are utilized. In case A, relatively weak southwesterly cross-Peninsula flow and an elevated upwind inversion dictate a highly nonlinear foehn event, with mountain wave breaking observed. The consequent strongly accelerated downslope flow leads to high-amplitude warming and ice-shelf melt in the immediate lee of the AP. However this foehn warming diminishes rapidly downwind due to upward ascent of the foehn flow via a hydraulic jump. In case C, strong northwesterly winds dictate a relatively linear flow regime. There is no hydraulic jump and strong foehn winds are able to flow at low levels across the entire ice shelf, mechanically mixing the near-surface flow, preventing the development of a strong surface inversion and delivering large fluxes of sensible heat to the ice shelf. Consequently, in case C ice-melt rates are considerably greater over the LCIS as a whole than in case A. Our results imply that although nonlinear foehn events cause intense warming in the immediate lee of mountains, linear foehn events will commonly cause more extensive lee-side warming and, over an ice surface, higher melt rates. This has major implications for the AP, where recent east-coast warming has led to the collapse of two ice shelves immediately north of the LCIS. [ABSTRACT FROM AUTHOR]

Published

2016

2. Foehn jets over the Larsen C Ice Shelf, Antarctica.

Author

Elvidge, Andrew D., Renfrew, Ian A., King, John C., Orr, Andrew, Lachlan‐Cope, Tom A., Weeks, Mark, and Gray, Sue L.

Subjects

*FOHN, *METEOROLOGICAL precipitation, *OROGRAPHIC clouds

Abstract

Previously unknown foehn jets have been identified to the east of the Antarctic Peninsula ( AP) above the Larsen C Ice Shelf. These jets have major implications for the east coast of the AP, a region of rapid climatic warming and where two large sections of ice shelf have collapsed in recent years. During three foehn events across the AP, leeside warming and drying is seen in new aircraft observations and simulated well by the Met Office Unified Model ( MetUM) at ∼1.5 km grid spacing. In case A, weak southwesterly flow and an elevated upwind inversion characterise a highly nonlinear flow regime with upwind flow blocking. In case C strong northwesterly winds characterise a relatively linear case with little upwind flow blocking. Case B resides somewhere between the two in flow regime linearity. The foehn jets - apparent in aircraft observations where available and MetUM simulations of all three cases - are mesoscale features (up to 60 km in width) originating from the mouths of leeside inlets. Through back trajectory analysis they are identified as a type of gap flow. In cases A and B the jets are distinct, being strongly accelerated relative to the background flow, and confined to low levels above the Larsen C Ice Shelf. They resemble the 'shallow foehn' of the Alps. Case C resembles a case of 'deep foehn', with the jets less distinct. The foehn jets are considerably cooler and moister relative to adjacent regions of calmer foehn air. This is due to a dampened foehn effect in the jet regions: in case A the jets have lower upwind source regions, and in the more linear case C there is less diabatic warming and precipitation along jet trajectories due to the reduced orographic uplift across the mountain passes. [ABSTRACT FROM AUTHOR]

Published

2015