Spatial and temporal ionospheric monitoring using broadband sferic measurements

The objective of this thesis is to use radio emissions from lightning, known as `radio atmospherics' or `sferics', to study the temporal and spatial variation of the lower ionosphere, a layer of ionized atmosphere beginning at $\sim$70 km altitude (D-region). Very Low Frequency (VLF, 3$-$3...

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Bibliographic Details
Main Author:	McCormick, Jackson C.
Other Authors:	Cohen, Morris B., Electrical and Computer Engineering, Steffes, Paul, Bibby, Malcolm, Simon, Sven
Format:	Thesis
Language:	English
Published:	Georgia Institute of Technology 2016
Subjects:	Ionosphere Remote sensing Sferics VLF (Very low frequency) Radio Solar flares Palmer Station Palmer-Station Antarc* Antarctica
Online Access:	http://hdl.handle.net/1853/54469

id	ftgeorgiatech:oai:smartech.gatech.edu:1853/54469
record_format	openpolar
spelling	ftgeorgiatech:oai:smartech.gatech.edu:1853/54469 2023-05-15T14:04:26+02:00 Spatial and temporal ionospheric monitoring using broadband sferic measurements McCormick, Jackson C. Cohen, Morris B. Electrical and Computer Engineering Steffes, Paul Bibby, Malcolm Simon, Sven 2016-01-07T17:40:38Z application/pdf http://hdl.handle.net/1853/54469 en_US eng Georgia Institute of Technology http://hdl.handle.net/1853/54469 Ionosphere Remote sensing Sferics VLF (Very low frequency) Radio Solar flares Text Thesis 2016 ftgeorgiatech 2023-03-27T17:54:43Z The objective of this thesis is to use radio emissions from lightning, known as `radio atmospherics' or `sferics', to study the temporal and spatial variation of the lower ionosphere, a layer of ionized atmosphere beginning at $\sim$70 km altitude (D-region). Very Low Frequency (VLF, 3$-$30kHz) radio waves are a useful diagnostic for lower ionospheric monitoring due to their reflection from this region and global propagation. Traditionally, the lower ionosphere has been sensed using single-frequency VLF transmitters allowing for analysis of a single propagation path, as there are only a small number of transmitters. A lightning stroke, however, releases an intense amount of impulsive broadband VLF radio energy in the form of a sferic, which propagates through the Earth-ionosphere waveguide. Lightning is globally distributed and very frequent, so a sferic is therefore also a useful diagnostic of the D-region. This is true both for ambient or quiet conditions, and for ionospheric perturbations such as solar flare x-ray bursts. Lightning strokes effectively act as separate VLF transmitting sources. As such, they uniquely provide the ability to add a spatial component to ionospheric remote sensing, in addition to their broadband signature which cannot be achieved with man-made transmitters. We describe the methods of processing in detail. As an example, we analyze a solar flare during which time there is a significant change in magnitude and frequency content of sferics. This disturbance varies with distance from the source, as well as time. We describe the methods of processing in detail, and show results at Palmer Station, Antarctica for both a quiet and active solar day. M.S. Thesis Antarc* Antarctica Georgia Institute of Technology: SMARTech - Scholarly Materials and Research at Georgia Tech Palmer Station ENVELOPE(-64.050,-64.050,-64.770,-64.770) Palmer-Station ENVELOPE(-64.050,-64.050,-64.770,-64.770)
institution	Open Polar
collection	Georgia Institute of Technology: SMARTech - Scholarly Materials and Research at Georgia Tech
op_collection_id	ftgeorgiatech
language	English
topic	Ionosphere Remote sensing Sferics VLF (Very low frequency) Radio Solar flares
spellingShingle	Ionosphere Remote sensing Sferics VLF (Very low frequency) Radio Solar flares McCormick, Jackson C. Spatial and temporal ionospheric monitoring using broadband sferic measurements
topic_facet	Ionosphere Remote sensing Sferics VLF (Very low frequency) Radio Solar flares
description	The objective of this thesis is to use radio emissions from lightning, known as `radio atmospherics' or `sferics', to study the temporal and spatial variation of the lower ionosphere, a layer of ionized atmosphere beginning at $\sim$70 km altitude (D-region). Very Low Frequency (VLF, 3$-$30kHz) radio waves are a useful diagnostic for lower ionospheric monitoring due to their reflection from this region and global propagation. Traditionally, the lower ionosphere has been sensed using single-frequency VLF transmitters allowing for analysis of a single propagation path, as there are only a small number of transmitters. A lightning stroke, however, releases an intense amount of impulsive broadband VLF radio energy in the form of a sferic, which propagates through the Earth-ionosphere waveguide. Lightning is globally distributed and very frequent, so a sferic is therefore also a useful diagnostic of the D-region. This is true both for ambient or quiet conditions, and for ionospheric perturbations such as solar flare x-ray bursts. Lightning strokes effectively act as separate VLF transmitting sources. As such, they uniquely provide the ability to add a spatial component to ionospheric remote sensing, in addition to their broadband signature which cannot be achieved with man-made transmitters. We describe the methods of processing in detail. As an example, we analyze a solar flare during which time there is a significant change in magnitude and frequency content of sferics. This disturbance varies with distance from the source, as well as time. We describe the methods of processing in detail, and show results at Palmer Station, Antarctica for both a quiet and active solar day. M.S.
author2	Cohen, Morris B. Electrical and Computer Engineering Steffes, Paul Bibby, Malcolm Simon, Sven
format	Thesis
author	McCormick, Jackson C.
author_facet	McCormick, Jackson C.
author_sort	McCormick, Jackson C.
title	Spatial and temporal ionospheric monitoring using broadband sferic measurements
title_short	Spatial and temporal ionospheric monitoring using broadband sferic measurements
title_full	Spatial and temporal ionospheric monitoring using broadband sferic measurements
title_fullStr	Spatial and temporal ionospheric monitoring using broadband sferic measurements
title_full_unstemmed	Spatial and temporal ionospheric monitoring using broadband sferic measurements
title_sort	spatial and temporal ionospheric monitoring using broadband sferic measurements
publisher	Georgia Institute of Technology
publishDate	2016
url	http://hdl.handle.net/1853/54469
long_lat	ENVELOPE(-64.050,-64.050,-64.770,-64.770) ENVELOPE(-64.050,-64.050,-64.770,-64.770)
geographic	Palmer Station Palmer-Station
geographic_facet	Palmer Station Palmer-Station
genre	Antarc* Antarctica
genre_facet	Antarc* Antarctica
op_relation	http://hdl.handle.net/1853/54469
_version_	1766275516495560704

Spatial and temporal ionospheric monitoring using broadband sferic measurements

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