The Temporal and Spatial Variability of the Marine Atmospheric Boundary Layer and Its Effect on Electromagnetic Propagation in and Around the Greenland Sea Marginal Zone

Variability of the MABL and its effect on the electromagnetic (EM) refractive structure around the Greenland Sea marginal ice zone were examined. Rawinsonde profiles and surface observations collected from 3 ships during MIZEX-87(20 March-11 April) served as the data set. A program, developed to cal...

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Bibliographic Details
Main Author: Groters, Douglas J.
Other Authors: NAVAL POSTGRADUATE SCHOOL MONTEREY CA
Format: Text
Language:English
Published: 1988
Subjects:
Atmospheric Physics
Physical and Dynamic Oceanography
Snow
Ice and Permafrost
Radiofrequency Wave Propagation
*ATMOSPHERIC REFRACTION
*MARINE ATMOSPHERES
*AIR WATER INTERACTIONS
EDGES
STRUCTURES
WIND
PATHS
THESES
BOUNDARY LAYER
HIGH PRESSURE
TRAPPING(CHARGED PARTICLES)
ELECTROMAGNETIC WAVE PROPAGATION
SURFACES
PROFILES
ICE
VERTICAL ORIENTATION
HETEROGENEITY
INVERSION
RADIOSONDES
REFRACTION
BAROMETRIC PRESSURE
MOISTURE
HEAT FLUX
RAY TRACING
SEA WATER
SEA ICE
OPEN WATER
GREENLAND SEA
LAYERS
CAPPING
ANOMALIES
SPATIAL DISTRIBUTION
MIZEX-88 EXPERIMENT
MARGINAL ICE ZONES
ATMOSPHERIC BOUNDARY LAYERS
REFRACTIVITY
SUPERREFRACTION
SUBREFRACTION
ELECTROMAGNETIC DUCTING
Greenland
Greenland Sea
Ice
permafrost
Sea ice
Online Access:http://www.dtic.mil/docs/citations/ADA200064
http://oai.dtic.mil/oai/oai?&verb=getRecord&metadataPrefix=html&identifier=ADA200064
Description
Summary:Variability of the MABL and its effect on the electromagnetic (EM) refractive structure around the Greenland Sea marginal ice zone were examined. Rawinsonde profiles and surface observations collected from 3 ships during MIZEX-87(20 March-11 April) served as the data set. A program, developed to calculate the refractivity at each vertical level of the rawinsonde profiles, also identified the levels at which trapping, superrefraction and subrefraction occurred. Temporal studies showed that a higher incidence of anomalous refractive layers occurred during periods when the region was under the influence of high pressure. More than 50% of the time, trapping and super- refractive layers were attributed to development of a capping inversion just above the MABL during these periods. Spatial studies showed that the refractive structure varied relative to distance from the ice edge as did the depth of the MABL. An upward slope in refractive layer heights was observed from the ice toward the open water. Significant spatial inhomogeneity was observed over horizontal ranges of less than 100 km. This was attributed to both the large- scale synoptic forcing affecting the region and to variations in the surface fluxes of heat and moisture over the ice and over the water. A range-dependent ray trace model developed at the Naval Ocean Systems Center was used to show how the ray paths of EM waves vary with a changing refractive structures. Keywords: Air water interactions, Greenland Sea, Atmospheric refraction, Electromagnetic wave propagation, Heat flux, Sea ice. Theses.

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