Identifying the driver of pulsating aurora

Y. Nishimura; J. Bortnik; W. Li; R. M. Thorne; L. R. Lyons; V. Angelopoulos; S. B. Mende; J. W. Bonnell; O. Le Contel; C. Cully; R. Ergun; U. Auster

doi:10.1126/science.1193186

Identifying the driver of pulsating aurora

Y. Nishimura
, J. Bortnik
, W. Li
, R. M. Thorne
, L. R. Lyons
, V. Angelopoulos
, S. B. Mende
, J. W. Bonnell
, O. Le Contel
, C. Cully
, R. Ergun
, U. Auster

Research output: Contribution to journal › Article › peer-review

Abstract

Pulsating aurora, a spectacular emission that appears as blinking of the upper atmosphere in the polar regions, is known to be excited by modulated, downward-streaming electrons. Despite its distinctive feature, identifying the driver of the electron precipitation has been a long-standing problem. Using coordinated satellite and ground-based all-sky imager observations from the THEMIS mission, we provide direct evidence that a naturally occurring electromagnetic wave, lower-band chorus, can drive pulsating aurora. Because the waves at a given equatorial location in space correlate with a single pulsating auroral patch in the upper atmosphere, our findings can also be used to constrain magnetic field models with much higher accuracy than has previously been possible.

Original language	English
Pages (from-to)	81-84
Number of pages	4
Journal	Science
Volume	330
Issue number	6000
DOIs	https://doi.org/10.1126/science.1193186
Publication status	Published - 1 Oct 2010

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title = "Identifying the driver of pulsating aurora",

abstract = "Pulsating aurora, a spectacular emission that appears as blinking of the upper atmosphere in the polar regions, is known to be excited by modulated, downward-streaming electrons. Despite its distinctive feature, identifying the driver of the electron precipitation has been a long-standing problem. Using coordinated satellite and ground-based all-sky imager observations from the THEMIS mission, we provide direct evidence that a naturally occurring electromagnetic wave, lower-band chorus, can drive pulsating aurora. Because the waves at a given equatorial location in space correlate with a single pulsating auroral patch in the upper atmosphere, our findings can also be used to constrain magnetic field models with much higher accuracy than has previously been possible.",

author = "Y. Nishimura and J. Bortnik and W. Li and Thorne, \{R. M.\} and Lyons, \{L. R.\} and V. Angelopoulos and Mende, \{S. B.\} and Bonnell, \{J. W.\} and \{Le Contel\}, O. and C. Cully and R. Ergun and U. Auster",

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doi = "10.1126/science.1193186",

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T1 - Identifying the driver of pulsating aurora

AU - Nishimura, Y.

AU - Bortnik, J.

AU - Li, W.

AU - Thorne, R. M.

AU - Lyons, L. R.

AU - Angelopoulos, V.

AU - Mende, S. B.

AU - Bonnell, J. W.

AU - Le Contel, O.

AU - Cully, C.

AU - Ergun, R.

AU - Auster, U.

PY - 2010/10/1

Y1 - 2010/10/1

N2 - Pulsating aurora, a spectacular emission that appears as blinking of the upper atmosphere in the polar regions, is known to be excited by modulated, downward-streaming electrons. Despite its distinctive feature, identifying the driver of the electron precipitation has been a long-standing problem. Using coordinated satellite and ground-based all-sky imager observations from the THEMIS mission, we provide direct evidence that a naturally occurring electromagnetic wave, lower-band chorus, can drive pulsating aurora. Because the waves at a given equatorial location in space correlate with a single pulsating auroral patch in the upper atmosphere, our findings can also be used to constrain magnetic field models with much higher accuracy than has previously been possible.

AB - Pulsating aurora, a spectacular emission that appears as blinking of the upper atmosphere in the polar regions, is known to be excited by modulated, downward-streaming electrons. Despite its distinctive feature, identifying the driver of the electron precipitation has been a long-standing problem. Using coordinated satellite and ground-based all-sky imager observations from the THEMIS mission, we provide direct evidence that a naturally occurring electromagnetic wave, lower-band chorus, can drive pulsating aurora. Because the waves at a given equatorial location in space correlate with a single pulsating auroral patch in the upper atmosphere, our findings can also be used to constrain magnetic field models with much higher accuracy than has previously been possible.

UR - https://www.scopus.com/pages/publications/77957368239

U2 - 10.1126/science.1193186

DO - 10.1126/science.1193186

M3 - Article

AN - SCOPUS:77957368239

SN - 0036-8075

VL - 330

SP - 81

EP - 84

JO - Science

JF - Science

IS - 6000

ER -

Identifying the driver of pulsating aurora

Abstract

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