New Science Opportunities with a Mid-Latitude SuperDARN Radar Raymond A. Greenwald Johns Hopkins University Applied Physics Laboratory.

Slides:

Advertisements

Similar presentations

SuperDARN is a network of HF radars (8-20 MHz) used to study the convection in the Earth's ionosphere at altitudes between 90 and 400 km and at magnetic.

Advertisements

Ionosphere Climate Studied by F3 / COSMIC Constellation C. H. Liu Academia Sinica In Collaboration with Tulasi Ram, C.H. Lin and S.Y. Su.

UARS Facilities Workshop: The SuperDARN Upper Atmosphere Facility J.M. Ruohoniemi, R.A. Greenwald, and J.B.H. Baker The Bradley Department of Computer.

E. Amata M. Candidi (1), M.F. Marcucci (1), S. Massetti (1), P. Francia (3), U. Villante (3) (1) Istituto di Fisica dello Spazio Interplanetario (IFSI),

Extended observations of decameter scatter associated with the mid-latitude ionospheric trough E. R. Talaat 1, E. S. Miller 1, R. J. Barnes 1, J. M. Ruohoniemi.

ESS 7 Lecture 14 October 31, 2008 Magnetic Storms

2011 SuperDARN Workshop, Hanover, NH 1 Solar cycle variability of atmospheric waves and tides as observed by SuperDARN Elsayed R. Talaat Johns Hopkins.

Peter Boakes 1, Steve Milan 2, Adrian Grocott 2, Mervyn Freeman 3, Gareth Chisham 3, Gary Abel 3, Benoit Hubert 4, Victor Sergeev 5 Rumi Nakamura 1, Wolfgang.

The EISCAT Radar Facilities Ian McCrea STFC RAL. What is EISCAT? International Scientific Association Established agreeement since 1975 First observations.

Figure 4: Overview of the geometry of the Rankin Inlet and Inuvik radar in MLT coordinates on Aug 08 th Merged vectors are shown in black. AMPERE.

Modelling the Thermosphere-Ionosphere Response to Space Weather Effects: the Problem with the Inputs Alan Aylward, George Millward, Alex Lotinga Atmospheric.

Adrian Grocott *, Steve Milan, Mark Lester, Tim Yeoman University of Leicester, U.K. *currently visiting NIPR, Japan Mervyn Freeman British Antarctic Survey,

Phase Coherence on Open Field Lines Associated with FLRs Abiyu Nedie, Frances Fenrich & Robert Rankin University of Alberta Edmonton, Alberta, Canada 2011.

O. M. Shalabiea Department of Physics, Northern Borders University, KSA.

Ionospheric Electric Field Variations during Geomagnetic Storms Simulated using CMIT W. Wang 1, A. D. Richmond 1, J. Lei 1, A. G. Burns 1, M. Wiltberger.

31 May 2011SuperDARN Workshop, 29 May - 3June 2011, Hanover, US 1 Short-period Doppler shift variations in the polar cap: ULF waves or something else?

11.1 Magnetic Dipole Field Magnetic Dipole Field (2) B 

Magnetosphere-Ionosphere Coupling through Plasma Turbulence at High- Latitude E-Region Electrojet Y. Dimant and M. Oppenheim Tuesday, April 13, 2010 Center.

Generation of field-aligned currents by solar wind impulse S. Fujita Meteorological College.

Figure 1: show a causal chain for how Joule heating occurs in the earth’s ionosphere Figure 5: Is of the same format as figure four but the left panels.

Julie A. Feldt CEDAR-GEM workshop June 26 th, 2011.

How do gravity waves determine the global distributions of winds, temperature, density and turbulence within a planetary atmosphere? What is the fundamental.

Tuija I. Pulkkinen Finnish Meteorological Institute Helsinki, Finland

Solar wind-magnetosphere- atmosphere coupling: effects of magnetic storms and substorms in atmospheric electric field variations Kleimenova N., Kozyreva.

UAFs Contribute To Major Science Programs Space Weather Global Change Space Missions.

Space Weather Major sources of space weather ● Solar wind – a stream of plasma consisting of high energy charged particles released from the upper atmosphere.

Ionospheric Effects during Severe Geomagnetic Storms John Foster MIT Haystack Observatory NASA CDAW Mar. 14, 2005.

How does the Sun drive the dynamics of Earth’s thermosphere and ionosphere Wenbin Wang, Alan Burns, Liying Qian and Stan Solomon High Altitude Observatory.

EISCAT Svalbard Radar studies of meso-scale plasma flow channels in the polar cusp ionosphere Y. Dåbakk et al.

University of Colorado 1 ; Delft University of Technology 2 ; University of Alaska 3 ; Centre National d’Etudes Spatiales 4 ; National Center for Atmospheric.

Magnetosphere-Ionosphere coupling processes reflected in

How does energy from magnetic storms get transferred from high to low latitudes Anthea Coster, MIT Haystack Observatory How does energy from magnetic storms.

JAXA’s Exploration of the Solar System Beyond the Moon and Mars.

Distributed Radar Networks Ray Greenwald JHU/APL.

Ionospheric Research at USU R.W. Schunk, L. Scherliess, J.J. Sojka, D.C. Thompson & L. Zhu Center for Atmospheric & Space Sciences Utah State University.

A generic description of planetary aurora J. De Keyser, R. Maggiolo, and L. Maes Belgian Institute for Space Aeronomy, Brussels, Belgium

Heliophysics Research Focus Areas for a new Heliophysics Roadmap A summary of suggested updates to the current RFA, and some possible outcomes.

Coupling of the Magnetosphere and Ionosphere by Alfvén Waves at High and Mid-Latitudes Bob Lysak, Yan Song, University of Minnesota, MN, USA Murray Sciffer,

Testing the Equipotential Magnetic Field Line Assumption Using SuperDARN Measurements and the Cluster Electron Drift Instrument (EDI) Joseph B. H. Baker.

CEDAR 2008 Workshop Observations at the Plasmaspheric Boundary Layer with the Mid-latitude SuperDARN radars Mike Ruohoniemi, Ray Greenwald, and Jo Baker.

PARTICLES IN THE MAGNETOSPHERE

Monitoring Space Weather with GPS Anthea J. Coster.

WG3 “Ionospheric Storms” Summary Report

Session SA33A : Anomalous ionospheric conductances caused by plasma turbulence in high-latitude E-region electrojets Wednesday, December 15, :40PM.

Ionospheric Science, Models and Databases at Haystack Observatory

Study on the Impact of Combined Magnetic and Electric Field Analysis and of Ocean Circulation Effects on Swarm Mission Performance by S. Vennerstrom, E.

Future China Geomagnetism Satellite Mission (CGS) Aimin Du Institute of Geology and Geophysics, CAS 2012/11/18 Taibei.

Mike Ruohoniemi 2012VT SuperDARN Remote Sensing of the Ionosphere and Earth’s Surface with HF Radar J. Michael Ruohoniemi and Joseph Baker.

Characteristics and source of the electron density irregularities in the Earth’s ionosphere Hyosub Kil Johns Hopkins University / Applied Physics Laboratory.

SS Special Section of JGR Space Physics Marks Polar’s 5th Anniversary September 4, 1996 This April special section is first of two Polar special sections.

30 April 2009 Space Weather Workshop 2009 The Challenge of Predicting the Ionosphere: Recent results from CISM. W. Jeffrey Hughes Center for Integrated.

Planetary waves in the equatorial mesosphere and ionosphere measurements Lourivaldo Mota Lima (UEPB) Luciana R. Araújo, Maxwelton F. Silva (UEPB) H. Takahashi,

Radiation Belt Storm Probes Mission and the Ionosphere-Thermosphere RPSP SWG Meeting June 2009.

VT SuperDARN Group Joseph Baker Ground-Based Observations of the Plasmapause Boundary Layer (PBL) Region with.

Baker Tech SuperDARN Large-Scale Observations of the Sub-Auroral Polarization Stream (SAPS) From.

near-Space Environment

Challenges The topological status of the magnetosphere: open or closed? Driver(s) of ionospheric sunward flow Source(s) of NBZ currents Key problem: are.

Paul Song Center for Atmospheric Research

CEDAR Frontiers: Daytime Optical Aeronomy Duggirala Pallamraju and Supriya Chakrabarti Center for Space Physics, Boston University &

The Ionosphere and Thermosphere GEM 2013 Student Tutorial

Atmosphere-Ionosphere Wave Coupling as Revealed in Swarm Plasma Densities and Drifts Jeffrey M. Forbes Department of Aerospace Engineering Sciences, University.

ICESTAR: Solar-terrestrial and aeronomy research during the International Polar Year Kirsti Kauristie1, Allan Weatherwax2, Richard Harrison3, Richard.

Evidence for Dayside Interhemispheric Field-Aligned Currents During Strong IMF By Conditions Seen by SuperDARN Radars Joseph B.H. Baker, Bharat Kunduri.

Ionosphere, Magnetosphere and Thermosphere Anthea Coster

CEDAR 2013 Workshop International space weather and climate observations along the 120E/60W meridional circle and its surrounding areas Space weather observations.

The Physics of Space Plasmas

Penetration Jet DMSP F April MLT

Earth’s Ionosphere Lecture 13

Dynamic Coupling between the Magnetosphere and the Ionosphere

Magnetosphere: Structure and Properties

Presentation transcript:

New Science Opportunities with a Mid-Latitude SuperDARN Radar Raymond A. Greenwald Johns Hopkins University Applied Physics Laboratory

SuperDARN Today and Tomorrow Northern Hemisphere Southern Hemisphere

Current SuperDARN Research Topics Global Convection Convection Dynamics Magnetosphere-Ionosphere Coupling Cusp and Boundary Layer Processes Plasma Instability Processes in the Auroral Zone and Polar Cap Gravity Waves Resonant MHD Waves Winds, Tides, and Planetary Waves Lower latitude SuperDARN radars will enhance and expand all of these research activities

Global Convection and Convection Dynamics Current emphasis High-latitude auroral zone and polar cap Quiet to moderately disturbed conditions Best for dayside measurements Benefits offered by mid-latitude radars Low-latitude boundary of convection remains in radar field-of-view under most conditions. Signals will traverse E-region before encountering diffuse auroral precipitation zone. New science opportunities Measurement of total nightside convection pattern even under disturbed and storm-time conditions. Measurement of F-region convection on diffuse auroral field lines.

Global Convection and Convection Dynamics New science opportunities Improved understanding of the dynamics of the low-latitude convection boundary. Undershielding Overshielding Improved understanding of how much convection is missed by the current radar configuration. Studies of the formation and evolution of sub-auroral plasma streams.

Magnetosphere-Ionosphere Coupling Current emphasis Coupling of high-latitude auroral zone and polar cap to outer magnetosphere, boundary layer, and cusp. Benefits offered by mid-latitude radars More measurements on inner magnetosphere field lines. New science opportunities Understand impact of overshielding and undershielding on M-I coupling Understand current, electric field, conductance relationships in low-latitude auroral zone and sub-auroral ionosphere. Obtain first definitive measurements of convection patterns on ring-current field lines

Ionospheric Structuring and Instability Processes Current emphasis Plasma instability processes on boundary layer and cusp field lines. Benefits offered by mid-latitude radars Views of ionospheric plasma processes at lower latitudes including the sub- auroral ionosphere. New science opportunities Investigate role of magnetospheric electric fields in forming sub-auroral plasma structures. Improved understanding of plasma sources to very high latitude ionosphere. Improved understanding of plasma instability processes in diffuse auroral zone and sub-auroral ionosphere.

Resonant MHD Waves Current emphasis Field-line resonances at very high latitudes. Wave coupling from solar wind to dayside magnetosphere. Benefits offered by mid-latitude radars Significantly increased data set from closed magnetic field-line domain. New science opportunities Profiling of field-line resonances throughout the inner magnetosphere. Determination of equatorial mass density profiles.

Gravity Waves Current emphasis Gravity wave generation at very high latitudes, particularly on dayside due to current surges. Benefits offered by mid-latitude radars Extended latitude coverage of gravity-wave formation and propagation. Opportunity for detection of gravity waves on nightside due to auroral zone processes. New science opportunities Understand growth and decay of equatorward-propagating gravity waves generated at high latitudes. Determine importance of gravity waves generated in the nighttime auroral zone.

Winds, Tidal Modes, and Planetary Waves Current emphasis Studies of the longitudinal structure of winds, tidal modes and planetary waves generated between 55  and 65  gg (~60  gm). Benefits offered by mid-latitude radars A consistent data set of measurements at 35  -40  gg (~45  gm). New research opportunities Multi-latitude and multi-longitude measurements of winds and planetary waves. Collaborations with non-SuperDARN MF and meteor radar researchers and well as atmospheric modelers.

Conclusions A mid-latitude SuperDARN network will expand our suite of observations to cover both mid and high latitude on field lines that map to both the inner and outer magnetosphere. The new data sets will be consistent with existing SuperDARN data sets, expanding and improving our views of a complex plasma system encompassing the Earth’s magnetosphere, ionosphere, and upper atmosphere. The combined data sets will yield: Improved understanding of the response of the M-I-A system to external drivers. Improved understanding of how and why the ionosphere evolves as it does.