I. The effect of volcanic aerosols on ultraviolet radiation in Antarctica. II. A novel method for enhancing subsurface radar imaging using radar interferometry

The theory of radiative transfer is used to explain how a stratospheric aerosol layer may, for large solar zenith angles, increase the flux of UV-B light at the ground. As previous explanations are heuristic and incomplete, I first provide a rigorous and complete explanation of how this occurs. I sh...

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Main Author: Tsitas, Steven R.
Format: Thesis
Language:English
Published: 1998
Subjects:
Antarc*
Antarctica
Online Access:https://thesis.library.caltech.edu/7456/
https://thesis.library.caltech.edu/7456/1/Tsitas%201998.pdf
https://resolver.caltech.edu/CaltechTHESIS:01302013-102418285
id ftcaltechdiss:oai:thesis.library.caltech.edu:7456
record_format openpolar
spelling ftcaltechdiss:oai:thesis.library.caltech.edu:7456 2023-09-05T13:12:46+02:00 I. The effect of volcanic aerosols on ultraviolet radiation in Antarctica. II. A novel method for enhancing subsurface radar imaging using radar interferometry Tsitas, Steven R. 1998 application/pdf https://thesis.library.caltech.edu/7456/ https://thesis.library.caltech.edu/7456/1/Tsitas%201998.pdf https://resolver.caltech.edu/CaltechTHESIS:01302013-102418285 en eng https://thesis.library.caltech.edu/7456/1/Tsitas%201998.pdf Tsitas, Steven R. (1998) I. The effect of volcanic aerosols on ultraviolet radiation in Antarctica. II. A novel method for enhancing subsurface radar imaging using radar interferometry. Dissertation (Ph.D.), California Institute of Technology. doi:10.7907/fc8p-nd23. https://resolver.caltech.edu/CaltechTHESIS:01302013-102418285 <https://resolver.caltech.edu/CaltechTHESIS:01302013-102418285> other Thesis NonPeerReviewed 1998 ftcaltechdiss https://doi.org/10.7907/fc8p-nd23 2023-08-14T17:28:31Z The theory of radiative transfer is used to explain how a stratospheric aerosol layer may, for large solar zenith angles, increase the flux of UV-B light at the ground. As previous explanations are heuristic and incomplete, I first provide a rigorous and complete explanation of how this occurs. I show that an aerosol layer lying above Antarctica during spring will decrease the integrated daily dose of biologically weighted irradiance, weighted by the erythema action spectrum, by only up to 5%. Thus after a volcanic eruption, life in Antarctica during spring will suffer the combined effects of the spring ozone hole and ozone destruction induced by volcanic aerosols, with the latter effect only slightly offset by aerosol scattering. I extend subsurface radar imaging by considering the additional information that may be derived from radar interferometry. I show that, under the conditions that temporal and spatial decorrelation between observations is small so that the effects of these decorrelations do not swamp the signature expected from a subsurface layer, the depth of burial of the lower surface may be derived. Also, the echoes from the lower and upper surfaces may be separated. The method is tested with images acquired by SIR-C of the area on the Egypt/Sudan border where buried river channels were first observed by SIR-A. Temporal decorrelation between the images, due to some combination of physical changes in the scene, changes in the spacecraft attitude and errors in the processing by NASA of the raw radar echoes into the synthetic aperture radar images, swamps the expected signature for a layer up to 40 meters thick. I propose a test to determine whether or not simultaneous observations are required, and then detail the radar system requirements for successful application of the method for both possible outcomes of the test. I also describe in detail the possible applications of the method. These include measuring the depth of burial of ice in the polar regions of Mars, enhancing the visibility of buried ... Thesis Antarc* Antarctica CaltechTHESIS (California Institute of Technology
institution Open Polar
collection CaltechTHESIS (California Institute of Technology
op_collection_id ftcaltechdiss
language English
description The theory of radiative transfer is used to explain how a stratospheric aerosol layer may, for large solar zenith angles, increase the flux of UV-B light at the ground. As previous explanations are heuristic and incomplete, I first provide a rigorous and complete explanation of how this occurs. I show that an aerosol layer lying above Antarctica during spring will decrease the integrated daily dose of biologically weighted irradiance, weighted by the erythema action spectrum, by only up to 5%. Thus after a volcanic eruption, life in Antarctica during spring will suffer the combined effects of the spring ozone hole and ozone destruction induced by volcanic aerosols, with the latter effect only slightly offset by aerosol scattering. I extend subsurface radar imaging by considering the additional information that may be derived from radar interferometry. I show that, under the conditions that temporal and spatial decorrelation between observations is small so that the effects of these decorrelations do not swamp the signature expected from a subsurface layer, the depth of burial of the lower surface may be derived. Also, the echoes from the lower and upper surfaces may be separated. The method is tested with images acquired by SIR-C of the area on the Egypt/Sudan border where buried river channels were first observed by SIR-A. Temporal decorrelation between the images, due to some combination of physical changes in the scene, changes in the spacecraft attitude and errors in the processing by NASA of the raw radar echoes into the synthetic aperture radar images, swamps the expected signature for a layer up to 40 meters thick. I propose a test to determine whether or not simultaneous observations are required, and then detail the radar system requirements for successful application of the method for both possible outcomes of the test. I also describe in detail the possible applications of the method. These include measuring the depth of burial of ice in the polar regions of Mars, enhancing the visibility of buried ...
format Thesis
author Tsitas, Steven R.
spellingShingle Tsitas, Steven R.
I. The effect of volcanic aerosols on ultraviolet radiation in Antarctica. II. A novel method for enhancing subsurface radar imaging using radar interferometry
author_facet Tsitas, Steven R.
author_sort Tsitas, Steven R.
title I. The effect of volcanic aerosols on ultraviolet radiation in Antarctica. II. A novel method for enhancing subsurface radar imaging using radar interferometry
title_short I. The effect of volcanic aerosols on ultraviolet radiation in Antarctica. II. A novel method for enhancing subsurface radar imaging using radar interferometry
title_full I. The effect of volcanic aerosols on ultraviolet radiation in Antarctica. II. A novel method for enhancing subsurface radar imaging using radar interferometry
title_fullStr I. The effect of volcanic aerosols on ultraviolet radiation in Antarctica. II. A novel method for enhancing subsurface radar imaging using radar interferometry
title_full_unstemmed I. The effect of volcanic aerosols on ultraviolet radiation in Antarctica. II. A novel method for enhancing subsurface radar imaging using radar interferometry
title_sort i. the effect of volcanic aerosols on ultraviolet radiation in antarctica. ii. a novel method for enhancing subsurface radar imaging using radar interferometry
publishDate 1998
url https://thesis.library.caltech.edu/7456/
https://thesis.library.caltech.edu/7456/1/Tsitas%201998.pdf
https://resolver.caltech.edu/CaltechTHESIS:01302013-102418285
genre Antarc*
Antarctica
genre_facet Antarc*
Antarctica
op_relation https://thesis.library.caltech.edu/7456/1/Tsitas%201998.pdf
Tsitas, Steven R. (1998) I. The effect of volcanic aerosols on ultraviolet radiation in Antarctica. II. A novel method for enhancing subsurface radar imaging using radar interferometry. Dissertation (Ph.D.), California Institute of Technology. doi:10.7907/fc8p-nd23. https://resolver.caltech.edu/CaltechTHESIS:01302013-102418285 <https://resolver.caltech.edu/CaltechTHESIS:01302013-102418285>
op_rights other
op_doi https://doi.org/10.7907/fc8p-nd23
_version_ 1776201675629920256

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