Your text would go here. Introduction References Current in geomagnetic storms By: J. Martínez 1 Faculty Advisors: J. Raeder 2, H. Vo 1, D. Cramer 2 University.

Slides:

Advertisements

Similar presentations

Stacking up the Atmosphere ELF Activity: Atmosphere 5A.

Advertisements

4/18 6:08 UT 4/17 6:09 UT Average polar cap flux North cap South cap… South cap South enter (need to modify search so we are here) South exit SAA Kress,

CHAMP Observations of Multiple Field-Aligned Currents Dimitar Danov 1, Petko Nenovski 2 Solar-Terrestrial Influences Laboratory, Bulgarian Academy of Sciences,

Comparing the solar wind-magnetosphere interaction at Mercury and Saturn A. Masters Institute of Space and Astronautical Science, Japan Aerospace Exploration.

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.

Solar system science using X-Rays Magnetosheath dynamics Shock – shock interactions Auroral X-ray emissions Solar X-rays Comets Other planets Not discussed.

Magnetospheric Morphology Prepared by Prajwal Kulkarni and Naoshin Haque Stanford University, Stanford, CA IHY Workshop on Advancing VLF through the Global.

Period 2. What is magnetic declination??? A) Magnetic declination is the angle between you and Earth when you are standing on a level surface. B) Magnetic.

The Earth and Its Moon Part 1: The Earth in Space 1.

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.

1 VIIRS DNB Aurora Event 7/15/2012 – 7/17/2012 William Straka III (CIMSS) utilizing data from Visualized in McIDAS-V 1.

Sponge: List the six layers of the Earth.. Atmosphere A mixture of gases: N 2 78% O 2 21% Ar0.9% CO %

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

Space Weather Alice Hirsh International Studies and Economics College of Arts and Sciences.

The Sun Our Nearest Star. The Source of the Sun’s Energy The Source of the Sun’s Energy Fusion of light elements into heavier elements. Hydrogen converts.

CR variation during the extreme events in November 2004 Belov (a), E. Eroshenko(a), G. Mariatos ©, H. Mavromichalaki ©, V.Yanke (a) (a) IZMIRAN), ,

Space Weather from Coronal Holes and High Speed Streams M. Leila Mays (NASA/GSFC and CUA) SW REDISW REDI 2014 June 2-13.

Comparison of the 3D MHD Solar Wind Model Results with ACE Data 2007 SHINE Student Day Whistler, B. C., Canada C. O. Lee*, J. G. Luhmann, D. Odstrcil,

C. J. Joyce, 1 N. A. Schwadron, 1 L. W. Townsend, 2 R. A. Mewaldt, 3 C. M. S. Cohen, 3 T. T. von Rosenvinge, 4 A. W. Case, 5 H. E. Spence, 1 J. K. Wilson,

Cynthia López-Portela and Xochitl Blanco-Cano Instituto de Geofísica, UNAM A brief introduction: Magnetic Clouds’ characteristics The study: Event types.

A.V. Belov 1, E. A. Eroshenko 1, H. Mavromichalaki 2, V.A. Oleneva 1, A. Papaioannou 2, G. Mariatos 2, V. G. Yanke 1 (1) Institute of Terrestrial Magnetism,

Nowcast model of low energy electrons (1-150 keV) for surface charging hazards Natalia Ganushkina Finnish Meteorological Institute, Helsinki, Finland.

The Sun- Solar Activity. Damage to communications & power systems.

Statistical properties of southward IMF and its geomagnetic effectiveness X. Zhang, M. B. Moldwin Department of Atmospheric, Oceanic, and Space Sciences,

29 August, 2011 Beijing, China Space science missions related to ILWS in China

In Nuclear fusion, four hydrogen atoms fuse together to form Helium and a lot of energy!

MAGNETOSPHERIC RESPONSE TO COMPLEX INTERPLANETARY DRIVING DURING SOLAR MINIMUM: MULTI-POINT INVESTIGATION R. Koleva, A. Bochev Space and Solar Terrestrial.

Stacking up the Atmosphere ELF Activity: Atmosphere 5A.

THE SUN. The Sun The sun has a diameter of 900,000 miles (>100 Earths could fit across it) >1 million Earths could fit inside it. The sun is composed.

Characteristics of Outer Planets

Solar cycle dependence of EMIC wave frequencies Marc Lessard, Carol Weaver, Erik Lindgren 1 Mark Engebretson University of New HampshireAugsburg College.

EARTHS MAGNETIC FIELD All about the “E.M.F”.

Tennessee SPI Objective: Check for Understanding Essential Question(s)

CSI 769 Fall 2009 Jie Zhang Solar and Heliospheric Physics.

What is a Tide? A tide is the rise and fall of the surface level of a body of water due to the Moon’s and the Sun’s gravitational pull.

C. J. Joyce, 1 N. A. Schwadron, 1 L. W. Townsend, 2 R. A. Mewaldt, 3 C. M. S. Cohen, 3 T. T. von Rosenvinge, 4 A. W. Case, 5 H. E. Spence, 1 J. K. Wilson,

The Geoeffectiveness of Solar Cycle 23 as inferred from a Physics-Based Storm Model LWS Grant NAG Principal Investigator: Vania K. Jordanova Institute.

Space Weather in Earth’s magnetosphere MODELS  DATA  TOOLS  SYSTEMS  SERVICES  INNOVATIVE SOLUTIONS Space Weather Researc h Center Masha Kuznetsova.

What we can learn from the intensity-time profiles of large gradual solar energetic particle events (LGSEPEs) ？ Guiming Le(1, 2,3), Yuhua Tang(3), Liang.

Introduction to Physical Science Monday, Wednesday, Thursday Tom Burbine

Acceleration, Reconnection, Turbulence and Electrodynamics of Moon's Interaction with the Sun.

1 The Solar Wind - Magnetosphere Coupling Function and Nowcasting of Geomagnetic Activity Leif Svalgaard Stanford University AMS-93, Austin, Jan

Particle precipitation has been intensely studied by ionospheric and magnetospheric physicists. As particles bounce along the earth's magnetic fields they.

1 SPACE WEATHER SPACE WEATHER. 2 Causes of space weather Space weather is caused mainly by storms and eruptions in our volatile Sun sending potentially.

Earth’s Magnetosphere Space Weather Training Kennedy Space Center Space Weather Research Center.

A survey of EMIC waves observed by the Van Allen probes between 02/01/2015 – 07/ E. Chapmann 2, A. R. Aly 1, J. -C. Zhang 1, AA. Saikin 1, C. W.

The Sun. Sun Fact Sheet The Sun is a normal G2 star, one of more than 100 billion stars in our galaxy. Diameter: 1,390,000 km (Earth 12,742 km or nearly.

Sponge: List the six layers of the Earth.

Chapter 19: Magnetic Forces and Fields

Tennessee SPI Objective: Essential Question(s)

NASA Van Allen Probes find Plasma Waves Influence the Shape and Shifting of Radiation around Earth NASA Heliophysics Van Allen Probes mission data provides.

Analyzing Sea Level Rise Due to Melting of Antarctic Ice

What You Should Know from “Light as a Wave”!

YOUR TITLE Your Name (Dr. Your Sponsor, Sponsor)

Effects of Dipole Tilt Angle on Geomagnetic Activities

The Not-So-Calm After the Storm:

Solar Activity and Space Weather

Computational Model of Energetic Particle Fluxes in the Magnetosphere

Chapter 7 The Jovian Planets

Quantification of solar wind parameters from measurments by SOHO and DSCOVR spacecrafts during series of Interplanetary Coronal Mass Ejections in the.

How Hurricanes Form Tropical Cyclones.

Notes Science SPI Magnetic Fields

Notes Science SPI Magnetic Fields I Can Statement

Grades 9-12: Introduction

Notes Science SPI Magnetic Fields I Can Statement

Added-Value Users of ACE Real Time Solar Wind (RTSW) Data

Engineering Design Process

CORONAL MASS EJECTIONS

Presentation transcript:

Your text would go here. Introduction References Current in geomagnetic storms By: J. Martínez 1 Faculty Advisors: J. Raeder 2, H. Vo 1, D. Cramer 2 University of New Hampshire 2, Department of Physics & Space Science | Universidad Del Turabo, PR 1 Results Introduction Data source Data Processing  The events were chosen on different shock angles. In the plots on Figure 1 and 2 different points of the Hemispheres of the planet are shown as the shock hits, the red represents currents going out and the blue represents currents going in.  As the shock in Figures 1 and 2 show, the current density is higher on the day side at the beginning of the event. After the shock passes to the night side a higher impact on the magnetosphere is seen, which causes greater current difference.  Plotting the change in total current in time it is shown how the difference in current rises. As it is shown in Figures 3, 4 and 5 the current initially is higher on the day side and then the current rises in the night side. In figure 4 it is shown how the night side current rises on the south side it’s much greater than the day side current in the south.  On the simulated data, the angles are:  IOS-1=150  IOS-2=135  FPS=180 Figure 2: Current density , south Figure 1: Current density , north Summary  Oliveira, D. M., and J. Raeder (2014), Impact angle control of interplanetary shock geoeffectiveness, J. Geophys. Res. Space Physics, 119,8188–8201, doi: /2014JA References We thank the AMPERE team and the AMPERE Science Center for providing the Iridium-derived data products. This Research was sponsored by The National Science Foundation under the grant AGS Acknowledgements Figure 4: current Figure 5: current Figure 6: current  Frequently the earth experiences Geomagnetic storms, events that cause a temporary disturbance on the earths magnetosphere. This is because the earth is hit by a solar wind shock wave or cloud of magnetic field. This creates a variation of currents in the magnetosphere of the earth.  If not for the protection of the magnetosphere would damage satellites orbiting the earth. These shocks cause electrical currents into and out of the Hemispheres. The log of electrical currents are available online in the AMPERE website ( which is obtained from the IRIDIUM satellites). This data was downloaded in the Net CDF format. On the ampere website there is also a IDL software provided for plotting the net CDF data.  It can be seen how the shocks have a profound impact on the magnetosphere. From these results it is shown the way the shock affects the earth.  It is shown in the plots that even though the shock hits first on the day side it is clear that a greater current difference in the night side. For most events after some time because of the shock.  The current changes depending on the angle of the shock. When angles are lower than 180 it is seen that the current rises faster on the night side after the initial shock on the day side. Figure 3: Simulated FAC  In Figure 3 it is shown that the simulated data although similar to the data from AMPERE The pattern stays very similar but magnitudes for day and night vary.