0.58 - 1.63 MeV Electrons 1.63 - 3.8 MeV Electrons 9 - 18 MeV Protons 18 - 30 MeV Protons CSSWE/REPTile measurements during Oct 3-8, 2013 - Plenty of ~0.6MeV.

Slides:

Advertisements

Similar presentations

THREE-DIMENSIONAL ANISOTROPIC TRANSPORT OF SOLAR ENERGETIC PARTICLES IN THE INNER HELIOSPHERE CRISM- 2011, Montpellier, 27 June – 1 July, Collaborators:

Advertisements

AB 11 22 33 44 55 66 77 88 99 10  20  19  18  17  16  15  14  13  12  11  21  22  23  24  25  26  27  28.

Electron Acceleration in the Van Allen Radiation Belts by Fast Magnetosonic Waves Richard B. Horne 1 R. M. Thorne 2, S. A. Glauert 1, N. P. Meredith 1.

Electron Acceleration inside Jupiter’s Radiation Belt and the Origin of Synchrotron Radiation Richard B. Horne 1 R. M. Thorne 2, S. A. Glauert 1, J. D.

Pitch-Angle Scattering of Relativistic Electrons at Earth’s Inner Radiation Belt with EMIC Waves Xi Shao and K. Papadopoulos Department of Astronomy University.

Radiation Belt Electron Pitch Angle Measurements from the GOES Satellites T. G. Onsager, J. C. Green, and H. J. Singer NOAA Geostationary Operational Environmental.

Ion Equatorial Distributions from Energetic Neutral Atom Images Obtained From IMAGE during Geomagnetic Storms Zhang, X. X., J. D. Perez, M.-C. Fok D. G.

Making a frequency distribution and histogram. The Data Make sure the data is quantitative Sort the data from smallest to largest Count how many.

Further development of modeling of spatial distribution of energetic electron fluxes near Europa M. V. Podzolko 1, I. V. Getselev 1, Yu. I. Gubar 1, I.

21 ECRS, Kosice, 12/09/2008 Trapped charge particles measurements in the radiation belt by PAMELA instrument Vladimir V. Mikhailov (MEPHI) for PAMELA collaboration.

Radiation Belt variations during current solar maximum

Interaction of Shear Alfven Waves (SAW) with Trapped Energetic Protons in the Inner Radiation Belt X. Shao, K. Papadopoulos, A. S. Sharma Department of.

CISM Radiation Belt Models CMIT Mary Hudson CISM Seminar Nov 06.

Accelerator hall of the S- DALINAC – electron energies from 2 to 130 MeV available – cw and pulsed beam operation possible – source for polarized electron.

Stanford Wave Induced Particle Precipitation (WIPP) Code Prajwal Kulkarni U.S. Inan, T.F. Bell March 4, 2008 Space, Telecommunications and Radioscience.

GAMMA-PARTICLE ARRAY FOR DIRECT REACTION STUDIES SIMULATIONS.

Finite Temperature Effects on VLF-Induced Precipitation Praj Kulkarni, U.S. Inan and T. F. Bell MURI Review February 18, 2009.

GLAST LAT Project23 Oct 2002 T. Burnett 1 Specifying particle fluxes in Gleam Toby Burnett.

RBSP-ECT Suite Status: Instrument Status and Instrument Operations Flexibility Harlan E. Spence on behalf of RBSP-ECT Team University of New Hampshire.

New Operational Algorithms for Charged Particle Data from Low-Altitude Polar-Orbiting Satellites J. L. Machol 1,2 *, J.C. Green 1, J.V. Rodriguez 3,4,

SC-A CIR Event 1 March 2013 CME Event 17 March 2013 SC-A SC-B Enhancement of Inner Zone Electron Fluxes Both events caused electron enhancements for

NEEP 541 Radiation Interactions Fall 2003 Jake Blanchard.

1 Introduction The TOP-modelPotential applicationsConclusion The Transient Observations-based Particle Model and its potential application in radiation.

Solar cycle dependence of EMIC wave frequencies Marc Lessard, Carol Weaver, Erik LindgrenMark Engebretson University of New HampshireAugsburg College Introduction.

Energetic charged particle injections at Saturn C. Paranicas 1, D. G. Mitchell 1, D. C. Hamilton 2, S. M. Krimigis 1, B. H. Mauk 1, P. C. Brandt 1, J.

SEP Forecast Product: Data Description Only Arik Posner 1,2 (1) Southwest Research Institute, San Antonio, TX (2) currently at NASA/HQ, SMD-Heliophysics.

ORBITALS Phase A Extended Interim Meeting U of A Phase A2 Work Update ORBITALS Science Team, University of Alberta CSA HQ, St. Hubert, 2010/03/17.

L ONG - TERM VERB CODE SIMULATIONS OF ULTRA - RELATIVISTIC ELECTIONS AND COMPARISON WITH V AN A LLEN P ROBES MEASUREMENTS Drozdov A. Y. 1,2, Shprits Y.

6/3/2016 Perkins AP Calculus AB Day 10 Section 4.4.

Dynamics of the Radiation Belts & the Ring Current Ioannis A. Daglis Institute for Space Applications Athens.

Meteoroid and debris models and tools in SPENVIS H. Ludwig D. Heynderickx BIRA, Ringlaan 3, B-1180 Brussel, Belgium.

Radiation damage calculation in PHITS

October CME Shock Event Hudson, Paral, Kress, Turner SWE ACE Solar Wind Electron Proton Alpha Monitor K0>5-Min

Low-Altitude Mapping of Ring Current and Radiation Belt Results Geoff Reeves, Yue Chen, Vania Jordanova, Sorin Zaharia, Mike Henderson, and Dan Welling.

Proposed project on lightning-induced electron precipitation (LEP) Lightning produces VLF waves that propagate globally in the Earth- ionosphere waveguide.

Trapped radiation models

Supporting Van Allen Probes science with the TS07D magnetic field model: Nowcasting electron intensities, global magnetic field distribution, and magnetic.

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

Theoretical Modeling of the Inner Zone Using GEANT4 Simulations as Inputs R. S. Selesnick and M. D. Looper The Aerospace Corp., Los Angeles, CA USA R.

Particle energization at Saturn C. Paranicas 1, E. Roussos 2, P. Kollmann 2, N. Krupp 2, J. F. Carbary 1, D. G. Mitchell 1, S. M. Krimigis 1, B. H. Mauk.

Applications of the GEM at high pressure for neutrons and X-rays T.L. van Vuure , R. Kreuger , C.W.E. van Eijk  and R.W. Hollander , L. M. S. Margato.

RAPID calibrations in the radiation belts Elena Kronberg 1 and Patrick W. Daly 1 (1)Max-Planck-Institute for Solar System Research, Katlenburg-Lindau,

Richard Thorne / UCLA Physical Processes Responsible for Relativistic Electron Variability in the Outer Radiation Zone over the Solar Cycle 1 Outline 2.

The Role of VLF Transmitters in Limiting the Earthward Penetration of Ultra-Relativistic Electrons in the Radiation Belts J. C. Foster, D. N. Baker, P.J.

Modelling Electron Radiation Belt Variations During Geomagnetic Storms with the new BAS Global Radiation Belt Model Richard B. Horne Sarah A. Glauert Nigel.

Photon Selection Algorithm Ming Yang ， Mingshui Chen BESIII Meeting

The propagation of Ultra High Energy Cosmic Rays in the Galactic magnetic fields A. Elyiv B. Hnatyk Astronomical Observatory of Kyiv National University,

Source and seed populations for relativistic electrons: Their roles in radiation belt changes A. N. Jaynes1, D. N. Baker1, H. J. Singer2, J. V. Rodriguez3,4.

GOES Data Status Mutual Benefits of NASA THEMIS and NOAA GOES

VNC: Application of Physics and Systems Science methodologies to Forecasting of the Radiation Belt Electron Environment S. N. Walker1, M. A. Balikhin1,

INTERCOMPARISON P3. Dose distribution of a proton beam

LET Performance Requirements Presenter: Richard Mewaldt

The most challenging consequences of Earth’s space environment occur in the inner radiation belt So far you have been hearing about sensational new results.

Details of Particle Motion

Search for local neutrino sources at BUST.

THEMIS and Space Weather

Vladimir Mikhailov (MEPhI) on behalf PAMELA collaboration

Ionospheric Effect on the GNSS Radio Occultation Climate Data Record

“Forward” vs “Reverse”

Name That Atom! Use your knowledge of atoms to find the name of each of the following atoms. Use a Periodic Table!

CRaTER-specific LRO Mission Duration Issues

Collaborators: Xin Tao, Richard M. Thorne

Example: If line AB is parallel to line CD and s is parallel to t, find the measure of all the angles when m< 1 = 100°. Justify your answers. t

Typical Vertical Resolution

Distance & Mid-Point Formulae

Average monthly temperature in Wellington and London

Picture 1 10 protons 10 neutrons = an electron.

Atomic Structure An atom is the smallest unit of matter

CHESS energy, 9x6 electrons and positrons, coupling tests

Max-Planck-Institut für extraterrestrische Physik

Presentation transcript:

MeV Electrons MeV Electrons MeV Protons MeV Protons CSSWE/REPTile measurements during Oct 3-8, Plenty of ~0.6MeV electrons in the inner zone, but not so for ~1.6 MeV electrons - Quantitative analysis on the >1 MeV electrons in the inner belt?

REPT a+b, Oct. 3-8, 2013, Range 2, E = 1.7, 2.5, 3.3, 4.1, 4.9 MeV ΔL=0.2, ΔE=0.2MeV, Δα=7.2 0, Δt=6days 4.5<L< <L< <L<1.5 Courtesy of Richard Selesnick of AFRL Pulse Height Analysis (PHA) on REPT high time resolution data Averaged equatorial pitch angle distribution based on PHA

REPT a+b, Oct. 3-8, 2013, Range 2, E = 1.7, 2.5, 3.3, 4.1, 4.9 MeV AE9 mean(solid) and AE8 max (dashed) E = 1.7, 2.5, 3.3, 4.1, 4.9 MeV Courtesy of Richard Selesnick and Bob Johnson of AFRL Both AE9 and AE8 show much higher electron fluxes (1.7, 2.5, and 3.3 MeV) in the inner zone than the upper limit bounded by REPT measurements