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Buoyancy Waves in Earth's Magnetosphere: Calculations for a 2‐D Wedge Magnetosphere
To improve theoretical understanding of the braking oscillations observed in Earth's inner plasma sheet, we have derived a theoretical model that describes k∥ = 0 magnetohydrodynamic waves in an idealized magnetospheric configuration that consists of a 2‐D wedge with circular‐arc field lines. T...
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| Published in: | Journal of geophysical research. Space physics 2018-05, Vol.123 (5), p.3548-3564 |
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| container_end_page | 3564 |
| container_issue | 5 |
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| container_title | Journal of geophysical research. Space physics |
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| creator | Wolf, R. A. Toffoletto, F. R. Schutza, A. M. Yang, J. |
| description | To improve theoretical understanding of the braking oscillations observed in Earth's inner plasma sheet, we have derived a theoretical model that describes k∥ = 0 magnetohydrodynamic waves in an idealized magnetospheric configuration that consists of a 2‐D wedge with circular‐arc field lines. The low‐frequency, short‐perpendicular‐wavelength mode obeys a differential equation that is often used to describe buoyancy oscillations in a neutral atmosphere, so we call those waves “buoyancy waves,” though the magnetospheric buoyancy force results from magnetic tension rather than gravity. Propagation of the wave is governed mainly by a position‐dependent frequency ωb, the “buoyancy frequency,” which is a fundamental property of the magnetosphere. The waves propagate if ωb > ω but otherwise evanesce. In the wedge magnetosphere, ωb turns out to be exactly the fundamental oscillation frequency for poloidal oscillations of a thin magnetic filament, and we assume that the same is true for the real magnetosphere. Observable properties of buoyancy oscillations are discussed, but propagation characteristics vary considerably with the state of the magnetosphere. For a given event, the buoyancy frequency and propagation characteristics can be determined from pressure and density profiles and a magnetic field model, and these characteristics have been worked out for one typical configuration. A localized disturbance that initially resembles a dipolarizing flux bundle spreads east‐west and also penetrates into the plasmasphere to some extent. The calculated amplitude near the center of the original wave packet decays in a few oscillation periods, even though our calculation includes no dissipation.
Plain Language Summary
Plasma in the near‐Earth region of space exhibits many kinds of ultralow‐frequency waves. The present paper deals with a specific class of space plasma ultralow‐frequency waves that have unique properties and have not been much studied. They can be called “buoyancy waves,” because they are mathematically equivalent to buoyancy waves in a neutral atmosphere, but the buoyancy force in near‐Earth space plasmas is due to magnetic tension rather than gravity. This paper develops a theory of near‐Earth space buoyancy waves, by considering a simplified geometry for which the wave equations can be solved analytically. The frequency and propagation characteristics of the waves are determined mainly by a parameter called the “buoyancy frequency,” which can be calcula |
| doi_str_mv | 10.1029/2017JA025006 |
| format | article |
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Plain Language Summary
Plasma in the near‐Earth region of space exhibits many kinds of ultralow‐frequency waves. The present paper deals with a specific class of space plasma ultralow‐frequency waves that have unique properties and have not been much studied. They can be called “buoyancy waves,” because they are mathematically equivalent to buoyancy waves in a neutral atmosphere, but the buoyancy force in near‐Earth space plasmas is due to magnetic tension rather than gravity. This paper develops a theory of near‐Earth space buoyancy waves, by considering a simplified geometry for which the wave equations can be solved analytically. The frequency and propagation characteristics of the waves are determined mainly by a parameter called the “buoyancy frequency,” which can be calculated from a mathematical model of near‐Earth space. Transient bursts of very rapid flow in Earth's magnetotail cause buoyancy waves in near‐Earth space. When one of these bursts encounters the strong magnetic field near the Earth, the flow brakes and oscillates a few times before coming to rest. That process generates buoyancy waves that spread out through a region of space, like a raindrop generates ripples in a pond. However, the magnetosphere is highly nonuniform, causing refraction and reflection.
Key Points
Braking of plasma sheet flow bursts generates buoyancy waves, which are similar to gravity waves in a neutral atmosphere
Theory predicts that these waves will be largely trapped between the plasmapause and plasma sheet but with some penetration into the plasmasphere
The wave amplitude in the main braking oscillation region dies away in a few wave periods, as the disturbance spreads out</description><identifier>ISSN: 2169-9380</identifier><identifier>EISSN: 2169-9402</identifier><identifier>DOI: 10.1029/2017JA025006</identifier><language>eng</language><publisher>Washington: Blackwell Publishing Ltd</publisher><subject>Atmosphere ; Brake presses ; Braking ; braking oscillations ; Buoyancy ; Bursting strength ; bursty bulk flows ; Computational fluid dynamics ; Configurations ; Differential equations ; Earth ; Earth magnetosphere ; Extremely low frequencies ; Fluid flow ; Gravitation ; magnetic buoyancy ; Magnetic fields ; Magnetic properties ; Magnetohydrodynamic waves ; Magnetohydrodynamics ; Magnetosphere ; Magnetotails ; Mathematical models ; Oscillations ; Plasmasphere ; Propagation ; Rapid flow ; Refraction ; Space plasmas ; ULF waves ; Wave equations ; Wave propagation ; Wedges</subject><ispartof>Journal of geophysical research. Space physics, 2018-05, Vol.123 (5), p.3548-3564</ispartof><rights>2018. American Geophysical Union. All Rights Reserved.</rights><lds50>peer_reviewed</lds50><oa>free_for_read</oa><woscitedreferencessubscribed>false</woscitedreferencessubscribed><citedby>FETCH-LOGICAL-c4118-49078f3f6fb097bb52f2ed47eb3857889b013cd262538d0323abed27d7a0d6473</citedby><cites>FETCH-LOGICAL-c4118-49078f3f6fb097bb52f2ed47eb3857889b013cd262538d0323abed27d7a0d6473</cites><orcidid>0000-0001-5291-4275</orcidid></display><links><openurl>$$Topenurl_article</openurl><openurlfulltext>$$Topenurlfull_article</openurlfulltext><thumbnail>$$Tsyndetics_thumb_exl</thumbnail><link.rule.ids>314,780,784,27924,27925</link.rule.ids></links><search><creatorcontrib>Wolf, R. A.</creatorcontrib><creatorcontrib>Toffoletto, F. R.</creatorcontrib><creatorcontrib>Schutza, A. M.</creatorcontrib><creatorcontrib>Yang, J.</creatorcontrib><title>Buoyancy Waves in Earth's Magnetosphere: Calculations for a 2‐D Wedge Magnetosphere</title><title>Journal of geophysical research. Space physics</title><description>To improve theoretical understanding of the braking oscillations observed in Earth's inner plasma sheet, we have derived a theoretical model that describes k∥ = 0 magnetohydrodynamic waves in an idealized magnetospheric configuration that consists of a 2‐D wedge with circular‐arc field lines. The low‐frequency, short‐perpendicular‐wavelength mode obeys a differential equation that is often used to describe buoyancy oscillations in a neutral atmosphere, so we call those waves “buoyancy waves,” though the magnetospheric buoyancy force results from magnetic tension rather than gravity. Propagation of the wave is governed mainly by a position‐dependent frequency ωb, the “buoyancy frequency,” which is a fundamental property of the magnetosphere. The waves propagate if ωb > ω but otherwise evanesce. In the wedge magnetosphere, ωb turns out to be exactly the fundamental oscillation frequency for poloidal oscillations of a thin magnetic filament, and we assume that the same is true for the real magnetosphere. Observable properties of buoyancy oscillations are discussed, but propagation characteristics vary considerably with the state of the magnetosphere. For a given event, the buoyancy frequency and propagation characteristics can be determined from pressure and density profiles and a magnetic field model, and these characteristics have been worked out for one typical configuration. A localized disturbance that initially resembles a dipolarizing flux bundle spreads east‐west and also penetrates into the plasmasphere to some extent. The calculated amplitude near the center of the original wave packet decays in a few oscillation periods, even though our calculation includes no dissipation.
Plain Language Summary
Plasma in the near‐Earth region of space exhibits many kinds of ultralow‐frequency waves. The present paper deals with a specific class of space plasma ultralow‐frequency waves that have unique properties and have not been much studied. They can be called “buoyancy waves,” because they are mathematically equivalent to buoyancy waves in a neutral atmosphere, but the buoyancy force in near‐Earth space plasmas is due to magnetic tension rather than gravity. This paper develops a theory of near‐Earth space buoyancy waves, by considering a simplified geometry for which the wave equations can be solved analytically. The frequency and propagation characteristics of the waves are determined mainly by a parameter called the “buoyancy frequency,” which can be calculated from a mathematical model of near‐Earth space. Transient bursts of very rapid flow in Earth's magnetotail cause buoyancy waves in near‐Earth space. When one of these bursts encounters the strong magnetic field near the Earth, the flow brakes and oscillates a few times before coming to rest. That process generates buoyancy waves that spread out through a region of space, like a raindrop generates ripples in a pond. However, the magnetosphere is highly nonuniform, causing refraction and reflection.
Key Points
Braking of plasma sheet flow bursts generates buoyancy waves, which are similar to gravity waves in a neutral atmosphere
Theory predicts that these waves will be largely trapped between the plasmapause and plasma sheet but with some penetration into the plasmasphere
The wave amplitude in the main braking oscillation region dies away in a few wave periods, as the disturbance spreads out</description><subject>Atmosphere</subject><subject>Brake presses</subject><subject>Braking</subject><subject>braking oscillations</subject><subject>Buoyancy</subject><subject>Bursting strength</subject><subject>bursty bulk flows</subject><subject>Computational fluid dynamics</subject><subject>Configurations</subject><subject>Differential equations</subject><subject>Earth</subject><subject>Earth magnetosphere</subject><subject>Extremely low frequencies</subject><subject>Fluid flow</subject><subject>Gravitation</subject><subject>magnetic buoyancy</subject><subject>Magnetic fields</subject><subject>Magnetic properties</subject><subject>Magnetohydrodynamic waves</subject><subject>Magnetohydrodynamics</subject><subject>Magnetosphere</subject><subject>Magnetotails</subject><subject>Mathematical models</subject><subject>Oscillations</subject><subject>Plasmasphere</subject><subject>Propagation</subject><subject>Rapid flow</subject><subject>Refraction</subject><subject>Space plasmas</subject><subject>ULF waves</subject><subject>Wave equations</subject><subject>Wave propagation</subject><subject>Wedges</subject><issn>2169-9380</issn><issn>2169-9402</issn><fulltext>true</fulltext><rsrctype>article</rsrctype><creationdate>2018</creationdate><recordtype>article</recordtype><recordid>eNp90MFKw0AQBuBFFCy1Nx9gwYMXo7OzSXbjrba1WiqCWHoMm2S3TYlJ3U2U3HwEn9EnMVIFvTiXGYaPGfgJOWZwzgCjCwQmZkPAACDcIz1kYeRFPuD-z8wlHJKBcxvoSnYrFvTI4qqpWlWmLV2qF-1oXtKJsvX61NE7tSp1XbntWlt9SUeqSJtC1XlVOmoqSxXFj7f3MV3qbKX_6iNyYFTh9OC798nievI4uvHm99Pb0XDupT5j0vMjENJwE5oEIpEkARrUmS90wmUgpIwSYDzNMMSAyww4cpXoDEUmFGShL3ifnOzubm313GhXx5uqsWX3MkboLkR-GAadOtup1FbOWW3irc2flG1jBvFXdvHv7DrOd_w1L3T7r41n04dh4CNK_glICG6g</recordid><startdate>201805</startdate><enddate>201805</enddate><creator>Wolf, R. A.</creator><creator>Toffoletto, F. R.</creator><creator>Schutza, A. M.</creator><creator>Yang, J.</creator><general>Blackwell Publishing Ltd</general><scope>AAYXX</scope><scope>CITATION</scope><scope>7TG</scope><scope>8FD</scope><scope>H8D</scope><scope>KL.</scope><scope>L7M</scope><orcidid>https://orcid.org/0000-0001-5291-4275</orcidid></search><sort><creationdate>201805</creationdate><title>Buoyancy Waves in Earth's Magnetosphere: Calculations for a 2‐D Wedge Magnetosphere</title><author>Wolf, R. A. ; Toffoletto, F. R. ; Schutza, A. M. ; Yang, J.</author></sort><facets><frbrtype>5</frbrtype><frbrgroupid>cdi_FETCH-LOGICAL-c4118-49078f3f6fb097bb52f2ed47eb3857889b013cd262538d0323abed27d7a0d6473</frbrgroupid><rsrctype>articles</rsrctype><prefilter>articles</prefilter><language>eng</language><creationdate>2018</creationdate><topic>Atmosphere</topic><topic>Brake presses</topic><topic>Braking</topic><topic>braking oscillations</topic><topic>Buoyancy</topic><topic>Bursting strength</topic><topic>bursty bulk flows</topic><topic>Computational fluid dynamics</topic><topic>Configurations</topic><topic>Differential equations</topic><topic>Earth</topic><topic>Earth magnetosphere</topic><topic>Extremely low frequencies</topic><topic>Fluid flow</topic><topic>Gravitation</topic><topic>magnetic buoyancy</topic><topic>Magnetic fields</topic><topic>Magnetic properties</topic><topic>Magnetohydrodynamic waves</topic><topic>Magnetohydrodynamics</topic><topic>Magnetosphere</topic><topic>Magnetotails</topic><topic>Mathematical models</topic><topic>Oscillations</topic><topic>Plasmasphere</topic><topic>Propagation</topic><topic>Rapid flow</topic><topic>Refraction</topic><topic>Space plasmas</topic><topic>ULF waves</topic><topic>Wave equations</topic><topic>Wave propagation</topic><topic>Wedges</topic><toplevel>peer_reviewed</toplevel><toplevel>online_resources</toplevel><creatorcontrib>Wolf, R. A.</creatorcontrib><creatorcontrib>Toffoletto, F. R.</creatorcontrib><creatorcontrib>Schutza, A. M.</creatorcontrib><creatorcontrib>Yang, J.</creatorcontrib><collection>CrossRef</collection><collection>Meteorological & Geoastrophysical Abstracts</collection><collection>Technology Research Database</collection><collection>Aerospace Database</collection><collection>Meteorological & Geoastrophysical Abstracts - Academic</collection><collection>Advanced Technologies Database with Aerospace</collection><jtitle>Journal of geophysical research. Space physics</jtitle></facets><delivery><delcategory>Remote Search Resource</delcategory><fulltext>fulltext</fulltext></delivery><addata><au>Wolf, R. A.</au><au>Toffoletto, F. R.</au><au>Schutza, A. M.</au><au>Yang, J.</au><format>journal</format><genre>article</genre><ristype>JOUR</ristype><atitle>Buoyancy Waves in Earth's Magnetosphere: Calculations for a 2‐D Wedge Magnetosphere</atitle><jtitle>Journal of geophysical research. Space physics</jtitle><date>2018-05</date><risdate>2018</risdate><volume>123</volume><issue>5</issue><spage>3548</spage><epage>3564</epage><pages>3548-3564</pages><issn>2169-9380</issn><eissn>2169-9402</eissn><abstract>To improve theoretical understanding of the braking oscillations observed in Earth's inner plasma sheet, we have derived a theoretical model that describes k∥ = 0 magnetohydrodynamic waves in an idealized magnetospheric configuration that consists of a 2‐D wedge with circular‐arc field lines. The low‐frequency, short‐perpendicular‐wavelength mode obeys a differential equation that is often used to describe buoyancy oscillations in a neutral atmosphere, so we call those waves “buoyancy waves,” though the magnetospheric buoyancy force results from magnetic tension rather than gravity. Propagation of the wave is governed mainly by a position‐dependent frequency ωb, the “buoyancy frequency,” which is a fundamental property of the magnetosphere. The waves propagate if ωb > ω but otherwise evanesce. In the wedge magnetosphere, ωb turns out to be exactly the fundamental oscillation frequency for poloidal oscillations of a thin magnetic filament, and we assume that the same is true for the real magnetosphere. Observable properties of buoyancy oscillations are discussed, but propagation characteristics vary considerably with the state of the magnetosphere. For a given event, the buoyancy frequency and propagation characteristics can be determined from pressure and density profiles and a magnetic field model, and these characteristics have been worked out for one typical configuration. A localized disturbance that initially resembles a dipolarizing flux bundle spreads east‐west and also penetrates into the plasmasphere to some extent. The calculated amplitude near the center of the original wave packet decays in a few oscillation periods, even though our calculation includes no dissipation.
Plain Language Summary
Plasma in the near‐Earth region of space exhibits many kinds of ultralow‐frequency waves. The present paper deals with a specific class of space plasma ultralow‐frequency waves that have unique properties and have not been much studied. They can be called “buoyancy waves,” because they are mathematically equivalent to buoyancy waves in a neutral atmosphere, but the buoyancy force in near‐Earth space plasmas is due to magnetic tension rather than gravity. This paper develops a theory of near‐Earth space buoyancy waves, by considering a simplified geometry for which the wave equations can be solved analytically. The frequency and propagation characteristics of the waves are determined mainly by a parameter called the “buoyancy frequency,” which can be calculated from a mathematical model of near‐Earth space. Transient bursts of very rapid flow in Earth's magnetotail cause buoyancy waves in near‐Earth space. When one of these bursts encounters the strong magnetic field near the Earth, the flow brakes and oscillates a few times before coming to rest. That process generates buoyancy waves that spread out through a region of space, like a raindrop generates ripples in a pond. However, the magnetosphere is highly nonuniform, causing refraction and reflection.
Key Points
Braking of plasma sheet flow bursts generates buoyancy waves, which are similar to gravity waves in a neutral atmosphere
Theory predicts that these waves will be largely trapped between the plasmapause and plasma sheet but with some penetration into the plasmasphere
The wave amplitude in the main braking oscillation region dies away in a few wave periods, as the disturbance spreads out</abstract><cop>Washington</cop><pub>Blackwell Publishing Ltd</pub><doi>10.1029/2017JA025006</doi><tpages>17</tpages><orcidid>https://orcid.org/0000-0001-5291-4275</orcidid><oa>free_for_read</oa></addata></record> |
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| language | eng |
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| source | Wiley-Blackwell Read & Publish Collection |
| subjects | Atmosphere Brake presses Braking braking oscillations Buoyancy Bursting strength bursty bulk flows Computational fluid dynamics Configurations Differential equations Earth Earth magnetosphere Extremely low frequencies Fluid flow Gravitation magnetic buoyancy Magnetic fields Magnetic properties Magnetohydrodynamic waves Magnetohydrodynamics Magnetosphere Magnetotails Mathematical models Oscillations Plasmasphere Propagation Rapid flow Refraction Space plasmas ULF waves Wave equations Wave propagation Wedges |
| title | Buoyancy Waves in Earth's Magnetosphere: Calculations for a 2‐D Wedge Magnetosphere |
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