Auroral Physics Research Articles

The green line: a chapter in the history of auroral physics

Helge Kragh examines the steps forward and false alarms on the way to understanding the green line, a key stage in the development of auroral physics.

Comment on “A turning point in auroral physics”] An apparent controversy in auroral physics

In his article “A turning point in auroral physics,” Bryant [2006] argued against what he called the ‘standard’ theory of auroral acceleration, according to which the electrons “gain their energy from static electric fields,” and offered wave acceleration as an alternative. Because of the importance of the process, not only for the aurora borealis but also for other cosmic plasmas, a clarification of this apparent controversy seems to b e in place.Indeed, theoretical descriptions of the acceleration process often use an electrostatic approach. One postulates or derives a quasi‐Ohm's Law for the relation between current density and potential drop along the magnetic field and attributes the energy gain of the electrons to the ‘fall’ through this potential drop. Strong confirmation comes from the findings that a ‘potential,’ derived from integrating the transverse electric field measured by a satellite crossing above an auroral arc, agrees well with the energy gain of ions accelerated below the spacecraft [e.g., McFadden et al., 1999]. The solution of the problem lies in the word ‘nearly’ In the height range of several thousand kilometers, where auroral acceleration is concentrated, the electric field is nearly electrostatic. In reality, it is applied by an electromagnetic Alfvén wave launched in the outskirts of the magnetosphere. When it reaches the stiff magnetic field near Earth, where its phase speed is close to the velocity of light, it traverses the acceleration region so fast that a nearelectrostatic description of the field is permissible. However, above the low magnetosphere the field continues as an induction field. In other words, auroral field lines are not equipotentials. In conclusion, Bryant is right in principle but wrong in discarding auroral acceleration by nearly electrostatic fields.

Reply to Comments on “A turning point in auroral physics”

Haerendel's conviction (An Apparent Controversy in Auroral Physics, Eos, this issue) that a potential difference is responsible for the downward acceleration of auroral electrons is based on there being an upward acceleration of positive ions, caused apparently by a corresponding electric field. However, even if one accepts on face value this indication of an upward directed quasi‐static electric field, the inevitable presence of a downward directed field farther along the line, where the equipotentials must close and the ions are slowed down again, prevents the negative potential well having any net effect on the energy of either ions or electrons traversing it. The conviction is therefore unfounded.Stern (Origin of Auroral Arcs, Eos, this issue) is swayed to the same conclusion by the fact that in order to deliver the necessary power, electrons need to be forced through the magnetic mirror field. Again, though, even setting aside the fact that static fields cannot produce net acceleration, the conclusion overlooks the fact that any process leading to downward acceleration will accomplish the same feat. Similarly, his claim that a voltage drop has been shown to exist is false. The measurements in question were of electrons, not electric fields. They demonstrate that downward acceleration occurs but do not reveal the process responsible.

Comment on “A turning point in auroral physics”] Origin of auroral arcs

In an article in Eos (57(39), 403, 26 September 2006), Duncan Bryant claimed “a turning point in auroral physics.” He credited the polar aurora to waves generated when positive tail ions interact with flanks of the magnetosphere. Unfortunately, auroral arcs need a stronger energy source, and electrons from the tail have a hard time penetrating the loss cone. The process could perhaps contribute to the electrons of 500–1000 eV in the plasma sheet, where their gradual escape creates the diffuse aurora observed by satellites, but not create the bright auroral arcs seen from the ground.

A turning point in auroral physics

Auroral studies have reached a turning point. It now seems clear that the ‘standard’ theory which claims that the electrons responsible for bright, curtain‐like auroral arcs gain their energy from static electric fields, is indefensible, while a theory which attributes the acceleration to plasma waves is poised as a possible successor.It was approximately 100 years ago that the Norwegian mathematician and physicist Kristian Birkeland inferred that the aurora was a scintillation of the atmosphere caused by an influx of charged particles. Just over half a century later, McIlwain [1960] discovered, from pioneering rocket flights made from near the town of Churchill in Manitoba, Canada, that Birkeland was right, and that the particles were primarily electrons. Moreover, Mcllwain was able to deduce that the electrons producing a curtain‐like auroral arc exhibited a local maximum, or peak, in their energy spectrum. This conclusion was confirmed with progressively increasing resolution and sensitivity by Albert [1967] and others in the 1960s.

SIERRA observations of Alfvénic processes in the topside auroral ionosphere

The NASA SIERRA rocket mission was a multiple‐payload, auroral plasma physics experiment that flew into a 100 nT auroral substorm at altitudes up to 735 km over the Poker Flat Research Range in Alaska on 14 January 2002. The flight environment was composed of an equatorward region of inverted‐V electron precipitation followed by a poleward region of mostly field‐aligned suprathermal electron bursts. In the inverted‐V region, the measured δE/δB implied a stationary field‐aligned current configuration. In the poleward region, the average electric field was much larger, 50 mV/m compared with 20 mV/m, included time‐varying components that exceeded 100 mV/m with periods of 0.5–5 s, and δE/δB was Alfvénic. Our multiple‐payload observations show that the perpendicular scale size of most of these waves is on the order of a kilometer or less. At smaller scales, broadband, extremely low‐frequency (BBELF) fluctuations associated with observed Alfvén waves had spectral ratios (δE/δB) appropriate for inertial Alfvén waves larger and smaller than the electron inertial length (λe = c/ωpe), but the phase angle differences between δE and δB indicate mostly propagating Alfvén waves for spatial scales much larger than λe and a transition to spatial perturbations, embedded in the plasma, for scales near λe. The data are consistent with the model of kilometer‐scale oblique Alfvénic arcs that are unstable to the current shear‐driven instabilities discussed in previous theoretical investigations, lending support to the conclusion that the observed BBELF fluctuations are likely driven by the wave‐associated field‐aligned current shear.

Martin Jacob Berger

Known as the father of electron and proton Monte Carlo methods, Martin Jacob Berger, chief of the radiation theory section of the National Bureau of Standards (now NIST) for more than 20 years, died in Bethesda, Maryland, on 6 November 2004 from the effects of a hematoma after a fall in which he struck his head.Born in Vienna in 1922, Martin left Austria in 1938 just before its annexation by Nazi Germany. After 18 months in England, he immigrated to the US in 1940 and earned a BS in physics from the University of Chicago three years later. He became a US citizen in 1944, joined the Army, and served in the Aleutian Islands until 1946. Shortly after his discharge, he began his graduate work at the University of Chicago and earned an MS (1948) and a PhD (1951), both in physics. He prepared his doctoral thesis under Marcel Schein on “Multiple Scattering of Fast Protons in Photographic Emulsions” and stayed on for a one-year postdoctoral fellow-ship in mathematical statistics.Martin had heard that Ugo Fano and Lew Spencer of NBS had been doing work on ionizing radiation, so he wrote to them, was invited for an interview, and was hired. In September 1952 he joined the radiation theory section, headed by Fano, within the atomic and radiation physics division, led by Lauriston Taylor. Twelve years later Martin became chief of the radiation theory section and was in charge of as many as 12 physicists; he held that position—through various reorganizations and a renaming—until his retirement in 1988.At NBS in the 1950s, Martin concentrated first on the transport of gamma rays and the development of photon Monte Carlo methods. He pioneered Monte Carlo calculations in complex media and extended them to realistic configurations involving boundaries and inhomogeneities. For the work on photon transport, Martin collaborated with colleagues in the radiation theory section to survey and compile cross-section information. One such colleague was Rosemary McGinnies, who wrote several important early evaluations. In 1960 Martin married Rosemary; they later had three children and six grandchildren. Over the years, Martin retained his interest in photon-interaction cross sections and collaborated on critically evaluated databases that have become a standard for radiation-transport calculations.Martin shifted his focus to charged-particle transport, with an emphasis on electrons and protons. His 1963 article “Monte Carlo Calculation of the Penetration and Diffusion of Fast Charged Particles,” which appeared in Methods in Computational Physics, thoroughly delineated the taxonomy, methods, underlying single- and multiple-scattering distributions, and algorithms used in charged-particle Monte Carlo codes. That work was a departure from the few earlier papers done by other authors mostly for calculations of showers in high-energy approximations. In his study, Martin developed a comprehensive approach in which he used the most accurate distributions available to describe the transport of radiation at energies of interest in medical and radiation-protection physics.With his 1963 paper, Martin literally established the modern Monte Carlo calculation of charged-particle transport. The methods he developed and the cross-section data for which he was largely responsible are imbedded in nearly all of today’s coupled photon–charged-particle Monte Carlo codes. The use of electron–photon Monte Carlo calculations are now widespread, and the field has matured so much that scientists in many disciplines now rely heavily on the results of the better-known Monte Carlo codes rather than much more difficult measurements. Perhaps the most telling compliment is that his early pioneering work is still remarkably relevant today, more than 40 years later.Martin was also responsible for an extensive body of critically evaluated radiation-interaction data. These data were not only necessary for his transport calculations but have become standard reference data for the radiological sciences. They include stopping powers and ranges for electrons, positrons, and heavy charged particles, and cross sections for the bremsstrahlung production by electrons and for the elastic scattering of electrons and positrons. During his Monte Carlo development work, Martin was also busily applying his methods to important problems in radiological physics. He calculated detector-response functions for radiation spectroscopy; performed microdosimetric calculations; and conducted numerous studies of the absorbed dose and the penetration of photons, electrons, bremsstrahlung, and protons in materials of interest in dosimetry, radiation protection, radiation shielding, auroral physics, and radioactivity standardization. After his retirement, he continued that work as a consultant for NBS and other agencies.Martin’s work was scientifically impeccable. He attacked each problem in his own way, which usually became the standard way. He frequently selected problems that others had not worked on and gave correct, straightforward, and useful solutions. In recognition of his enduring contributions, the International Commission on Radiation Units and Measurements awarded Martin its L. H. Gray Medal in 2003.The radiological community has lost an important scientist. Martin Jacob Berger PPT|High resolution© 2005 American Institute of Physics.

Some recent developments in understanding auroral electron acceleration processes

Discrete auroral arcs and the associated inverted-V-type electron precipitation are accompanied by potential structures, upgoing ion beams and plasma density depletions in the acceleration region altitude and above. However, exactly how these phenomena depend on altitude in various Kp and solar illumination conditions as well as at various magnetic local time (MLT) and invariant latitude (ILAT) is not so well known. We review the main results of our recent large statistical studies of the altitude dependence of these parameters using Polar data. We also include similar statistical results on some additional parameters that appear to have major importance in inverted-V auroral acceleration. These parameters include middle-energy (/spl sim/50-500 eV) electron anisotropies, certain types of electrostatic wave bursts as well as ion shell distributions. One of the most interesting results of the statistical studies is that many of the parameters mentioned change their behavior rather abruptly at around 4 R/sub E/ radial distance. We draw the conclusion that the region for auroral energization processes seems to take place within a closed potential structure below /spl sim/3-4 R/sub E/. These conclusions lead to a new scenario for auroral plasma physics and the energy flow in the auroral acceleration process. The observational results are in agreement with simulations that we also summarize in this paper.

Excitation of tall auroral rays by ohmic heating in field‐aligned current filaments at F region heights

The formation of tall red rays in the ionosphere has been a longstanding unresolved problem of auroral physics. These rays are pencil‐like structures which can extend from 150 km at their base to as high as 600 km. At these heights it is very difficult to deposit sufficient power in order to account for the luminosity of tall rays. This work examines ohmic heating by collisional processes in strong field‐aligned current sheets to account for visible tall rays. The mechanism is demonstrated by two‐dimensional simulation in a fully self‐consistent treatment of the ionosphere and coupling to the magnetosphere. We find that a filamentary current density of about 600 μAm−2 over about ten seconds can pump sufficient energy into the ambient oxygen atoms to produce visible auroral red rays. The ohmic heating leads to an electron temperature in excess of 10,000 K in the upper F‐region.

Double layers in expanding plasmas and their relevance to the auroral plasma processes

When a dense plasma consisting of a cold and a sufficiently warm electron population expands, a rarefaction shock forms [Bezzerides et al., 1978]. In the expansion of the polar wind in the magnetosphere, it has been previously shown that when a sufficiently warm electron population also exists, in addition to the usual cold ionospheric one, a discontinuity forms in the electrostatic potential distribution along the magnetic field lines [Barakat and Schunk, 1984]. Despite the lack of spatial resolution and the assumption of quasi‐neutrality in the polar wind models, such discontinuities have been called double layers (DLs). Recently similar discontinuities have been invoked to partly explain the auroral acceleration of electrons and ions in the upward current region [Ergun et al., 2000]. By means of one‐dimensional Vlasov simulations of expanding plasmas, for the first time we make here the connection between (1) the rarefaction shocks, (2) the discontinuities in the potential distributions, and (3) DLs. We show that when plasmas expand from opposite directions into a deep density cavity with a potential drop across it and when the plasma on the high‐potential side contains hot and cold electron populations, the temporal evolution of the potential and the plasma distribution generates evolving multiple double layers with an extended density cavity between them. One of the DLs is the rarefaction‐shock (RFS) and it forms by the reflections of the cold electrons coming from the high‐potential side; it supports a part of the potential drop approximately determined by the hot electron temperature. The other DLs evolve from charge separations arising either from reflection of ions coming from the low‐potential side or stemming from plasma instabilities; they support the rest of the potential drop. The instabilities forming these additional double layers involve electron‐ion (e‐i) Buneman or ion‐ion (i‐i) two‐stream interactions. The electron‐electron two‐stream interactions on the high‐potential side of the RFS generate electron‐acoustic waves, which evolve into electron phase‐space holes. The ion population originating from the low‐potential side and trapped by the RFS is energized by the e‐i and i‐i instabilities and it eventually precipitates into the high‐potential plasma along with an electron beam. Applications of these findings to the auroral plasma physics are discussed.

Diagnostics of magnetosphere-ionosphere coupling over Indian Antarctic station Maitri, from magnetometer and riometer observations during the optical auroral event of 4–5 March 1999

A splendid display of “aurora australis” was observed over the Indian Antarctic station Maitri (geomag. lat. 62°.8 S, long. 52°.8 E; L = 4.8) on the night of 4–5 March 1999. The changes recorded by a fluxgate magnetometer, and a 30 MHz riometer operating at Maitri are interpreted in terms of currently - understood auroral physics. Interplanetary magnetic field and plasma parameters recorded by the WIND satellite indicate very high solar wind velocities (500–600 km/s), and prolonged southward B z of average value (∼ 5 nT), during the auroral event. Ion density is however an average 3–4/cm 3, and Ion pressure only 2–3 nano Pascals during the event.

Yuri I. Galperin (1932–2001)

Yuri I. Galperin, head of the Laboratory of Auroral Physics Phenomena at the Space Research Institute of the Russian Academy of Sciences, passed away on 28 December 2001 due to a heart attack. He was a pioneer of auroral and upper atmospheric physics and contributed significantly to the development of space plasma physics. He had been an AGU member (SM) since 1974.Galperin authored and co‐authored more than 200 publications in scientific journals and was a co‐author of three monographs on experimental space physics. In addition to AGU, Galperin was a member of many scientific councils in Russia, and he had also been a member of the International Astronomical Union since 1958 and the International Academy of Astronautics since 1975.

Cluster, Equator-S and the magnetosphere

The article provides a quick tour through auroral and magnetospheric plasma physics. New insights to be gained by a successful Cluster mission concern the dynamic role of three-dimensional and small-scale structures in the interaction with the solar wind and the coverage of the coldest plasma constituents. This will be measurable by controlling the spacecraft potential.

Wilhelm Foerster and The Development of Solar-Terrestrial Physics

Extracts from William Foerster’s papers relating to geomagnetism, solar and auroral physics are presented here so as to give an idea about his contribution to the solar-terrestrial physics during the years 1871 to 1906.

SMALL SCALE ALFVÉNIC STRUCTURE IN THE AURORA

This paper presents a comprehensive review of dispersive Alfven waves in space and laboratory plasmas. We start with linear properties of Alfven waves and show how the inclusion of ion gyroradius, parallel electron inertia, and finite frequency effects modify the Alfven wave properties. Detailed discussions of inertial and kinetic Alfven waves and their polarizations as well as their relations to drift Alfven waves are presented. Up to date observations of waves and field parameters deduced from the measurements by Freja, Fast, and other spacecraft are summarized. We also present laboratory measurements of dispersive Alfven waves, that are of most interest to auroral physics. Electron acceleration by Alfven waves and possible connections of dispersive Alfven waves with ionospheric-magnetospheric resonator and global field-line resonances are also reviewed. Theoretical efforts are directed on studies of Alfven resonance cones, generation of dispersive Alfven waves, as well their nonlinear interactions with the background plasma and self-interaction. Such topics as the dispersive Alfven wave ponderomotive force, density cavitation, wave modulation/filamentation, and Alfven wave self-focusing are reviewed. The nonlinear dispersive Alfven wave studies also include the formation of vortices and their dynamics as well as chaos in Alfven wave turbulence. Finally, we present a rigorous evaluation of theoretical and experimental investigations and point out applications and future perspectives of auroral Alfven wave physics.

Wilhelm Foerster and the development of solar and cosmical physics

Extracts from Foerster's papers relating to geomagnetism, solar and auroral physics are presented here so as to give an idea about his contribution to the solar-terrestrial physics during the years 1871-1906

First results from the energetic particle instrument on the OEDIPUS-C sounding rocket

The Canadian / US OEDIPUS-C rocket was flown form the Poker Flat Rocket Range November 6th 1995 as a mother-son sounding rocket. It was designed to study auroral ionospheric plasma physics using active wave sounding and prove tether technology. The payload separated into two sections reaching a separation of 1200m along the Earth's magnetic field. One section included a frequency stepped HF transmitter and the other included a synchronised HF receiver. Both sections included Energetic Particle Instruments, EPI, stepped in energy synchronously with the transmitter steps. On-board EPI particle processing in both payloads provided direct measurements of electron heating, wave-particle interactions via particle correlators, and a high resolution measurement of wave induced particle heating via transmitter synchronised fast sampling. Strong electron heating was observed at times when the HF transmitter frequency was equal to a harmonic of the electron gyrofrequency, f ce, or equal to the upper hybrid frequency, f uh.

Horwitz starts term as EosSPA Editor

James L. Horwitz began his term as Eos section editor for Space Phyics and Aeronomy in January. He is professor of physics and associate director of the Center for Space Plasma and Aeronomic Research (CSPAR) at The University of Alabama in Huntsville. Horwitz obtained a B.A. in Physics with highest Honors from the University of California in San Diego in 1970. He received his M.S. and Ph.D. degrees from the same institution, in 1972 and 1976, respectively. His Ph.D. dissertation title was “Radar Measurements of Electric Fields in the High Latitude Ionosphere and Other Topics in Auroral Physics.” In 1976, Horwitz entered the NASA Marshall Space Flight Center as an NAS/NRC Research Associate, analyzing low‐energy plasma data from instruments aboard the ATS‐6 and ISEE‐1 satellites.

Validation of techniques for space based remote sensing of auroral precipitation and its ionospheric effects

Knowledge of the spatial distribution of auroral precipitation and its associated ionospheric effects is important both to scientific studies of the Earth's environment and successful operation of defense and communication systems. Observations with the best spatial and temporal coverage are obtained through remote sensing from space-based platforms. Various techniques have been used, including the detection of visible, ultraviolet and X-ray emissions produced by the precipitating particles. Interpretation of the measurements is enabled through theoretical modeling of the interaction of precipitating particles with atmospheric constituents. A great variety of auroral precipitation exists, with each kind differing in the type and energy distribution of the particles, as well as in its spatial and temporal behavior. Viable remote sensing techniques must be able to distinguish at least the species of particle, the total energy flux, and the average energy. Methods based on visible, ultraviolet and X-ray emissions meet these requirements to varying degrees. These techniques and the associated space instrumentation have evolved in parallel over the last two decades. Each of the methods has been tested using simultaneous measurements made by space-based imaging systems and ground-based measurements made by radars and optical instruments. These experiments have been extremely helpful in evaluating the performance and practicality of the instruments and the results have been crucial in improving instrument design for future remote sensing platforms. The next decade will see continued development and test of remote sensing instruments and the measurements, in addition to providing important operational data, will be increasingly more critical in addressing a number of scientific problems in auroral and atmospheric physics.

An alternative interpretation of auroral precipitation and luminosity observations from the DE, DMSP, AUREOL, and Viking satellites in terms of their mapping to the nightside magnetosphere

We present an interpretation, which differs from that commonly accepted, of several published case studies of the patterns of auroral electron precipitation into the high-latitude upper atmosphere in the near-midnight sector based on their mapping to the nightside magnetosphere. In our scheme bright discrete auroral structures of the oval and respective precipitation are considered to be on the field lines of the Central, or Main, Plasma Sheet at distances from 5–10 to 30–50 R E , depending on activity. This auroral electron precipitation pattern was discussed in detail by Feldstein and Galperin [(1985) Rev. Geophys. 23, 217] and Galperin and Feldstein [(1991) Auroral Physics, p. 207. Cambridge University Press. It is applied and shown to be consistent with the results of case studies based on selected transpolar passes of the DE, DMSP, AUREOL-3 and Viking satellites. A diagram summarising the polar precipitation regions and their mapping from the magnetospheric plasma domains is presented. It can be considered as a modification of the Lyons and Nishida (1988) scheme which characterizes the relationship between the gross magnetospheric structure and regions of nightside auroral precipitation. The modification takes into account non-adiabatic ion motions in the tail neutral sheet, so that the ion beams characteristic of the Boundary Plasma Sheet (BPS) originate on closed field lines of the distant Central Plasma Sheet (say, at distances more than ~30 R E ).