logging in or signing up SW Intro Viereck WoodRock Download Post to : URL : Related Presentations : Share Add to Flag Embed Email Send to Blogs and Networks Add to Channel Uploaded from authorPOINTLite Insert YouTube videos in PowerPont slides with aS Desktop Copy embed code: (To copy code, click on the text box) Embed: URL: Thumbnail: WordPress Embed Customize Embed The presentation is successfully added In Your Favorites. Views: 100 Category: Education License: All Rights Reserved Like it (1) Dislike it (0) Added: January 03, 2008 This Presentation is Public Favorites: 0 Presentation Description No description available. Comments Posting comment... Premium member Presentation Transcript Space Weather: What is it? How Will it Affect You? : Space Weather: What is it? How Will it Affect You? An introduction to Space Weather What is it? Where does it come from? What does it do? Rodney Viereck NOAA Space Environment Center Boulder ColoradoSpace Weather: What is it?: Space Weather: What is it? Space Weather refers to changes in the space environment near Earth Earth Sun Sun: Energy (386 Billion Billion MegaWatts) released in the form of… Light Particles (electrons and protons) Magnetic Field Activity Cycles 27 Days (solar rotation) ~100 Days Active Region Development 11 years 22 years 88 yearsGOES Solar X-Rays: GOES Solar X-Rays Space weather events are usually initiated by a solar flare or a coronal mass ejection During a solar flare, the x-ray irradiance can increase by several orders of magnitude in just a few minutesSpace Weather: What is it?: Space Weather refers to changes in the space environment near Earth Sun Interplanetary Space: Solar Wind Constant outflow from the sun Electrons and protons Disturbances from the sun produce waves and shocks in the solar wind Interplanetary Space Space Weather: What is it? EarthACE Solar Wind: ACE Solar Wind Solar Wind Density 1 to 100 particles per cm3 Speed 200 to 800 km/secSlide6: Space Weather refers to changes in the space environment near Earth Magnetosphere Magnetosphere: Created by Earth’s magnetic field Deformed by the Solar Wind Particles (electrons and protons) trapped on magnetic field lines Sun Interplanetary Space Space Weather: What is it? EarthGOES Particles and Magnetic Field: GOES Particles and Magnetic Field Protons Electrons Magnetic FieldSlide8: Space Weather refers to changes in the space environment near Earth Magnetosphere Sun Interplanetary Space Ionosphere Ionosphere: Layer of electrons at the top of the atmosphere (100 – 300 km up) Formed when extreme ultraviolet light from the sun hits Earth’s Atmosphere Strongly affected by changes in the magnetosphere Critical in the reflection and transmission of radio waves Space Weather: What is it? EarthPOES Ionospheric Particles: POES Ionospheric Particles Auroral Oval Electrons and Protons collide with the atmosphere The collisions excite atoms and molecules to produce the auroraOther Space Weather Terms: Other Space Weather Terms Solar Flare: An eruption on the sun that emits light (UV and x-rays) and often particles (electrons and protons). CME (Coronal Mass Ejection): A disturbance in the solar wind caused by an eruption on the sun. Solar Wind: The outward flow of electrons, protons, and magnetic field from the sun. Energetic Particles: electrons and protons that have been accelerated to high speeds. Geomagnetic Storm: The disturbance in the near-Earth particles and magnetic fields that can upset technological systems and creates aurora. Radiation Storm: A large flux of solar energetic protons as measured near Earth. Radio Blackout: An enhancement in the lower ionosphere as a result of large x-ray flares. Sequence Of Events: Sequence Of Events Active Region on the Sun Erupts Solar Flare (x-ray) Shock (energetic particles) Corornal Mass Ejection (particles and fields) X-rays reach Earth in 8 minutes (speed of light) Energetic Particles reach Earth in 15 min to 24 hours Coronal Mass Ejection reaches Earth in 1-4 DaysThree Types of Space Weather Storms: Three Types of Space Weather Storms Radio Blackouts Solar Flares send out x-rays Arrive at Earth in 8 minutes Modify the ionosphere Disrupt HF radio communication Impacts: Airline communication HF radio operators DoD Communications Satellite Communications Radiation Storms Solar Flares and Coronal Mass Ejections (CMEs) send out Energetic Particles Arrive at Earth in 15 minutes to 24 hours Modify the high latitude ionosphere Disrupt HF radio communication Impacts: Airline communication HF radio operators DoD Communications Ionizing radiation penetrates into the atmosphere Impacts: Astronauts (radiation) Satellite failures Geomagnetic Storms Coronal Mass Ejections (CMEs) send out Magnetic Clouds Arrive at Earth in 1-4 days Accelerate particles within the magnetosphere and into the ionosphere Impacts: HF radio communication Radio Navigation (GPS) Electric Power Grids Increased Satellite Drag AuroraThe Sun The Energy Source: The Sun The Energy Source The sun in X-rays From GOES 12 The Sun Rotates every 27 days Has an 11-year cycle of activity Flares produce large amounts of x-rays and extreme ultraviolet light but not much visible light An Erupting Prominence A Solar Flare Image from NASA TRACE Satellite Image from NASA SOHO SatelliteSolar Photons (Light): Solar Photons (Light) Visible light (small slow changes) Most of the energy output Impacts climate UV light (medium slow changes) Affects ozone production and loss EUV light (large changes) Affects radio communication Affects navigation Affects satellite orbits X-ray light (Can change by a factor of 1000 in five minutes) Affects radio communication Solar spectrum Solar variability Atmospheric penetration X-Ray Flare Variability (minutes) LeanProduct for Radio Operators: Product for Radio Operators TJFRCMEs (Coronal Mass Ejections) in Interplanetary Space: CMEs (Coronal Mass Ejections) in Interplanetary Space While Solar flares send out light (mostly x-rays) CMEs produce… Energetic particles Magnetic structures Propagate away from the sun but their paths are modified by the background solar wind and the sun’s magnetic field. Image from NASA SOHO Satellite Image from NASA SOHO SatelliteMagnetosphere: Magnetosphere What happens when a CME hits Earth? Solar wind is deflected around Earth Deflected solar wind drags Earth’s magnetic field with it Magnetic field lines “reconnect” and accelerate particles Accelerated particles follow field lines to Earth Aurora is produced when particles hit Earth’s atmosphere 1. Solar wind is deflected around Earth 2. Deflected solar wind drags Earth’s magnetic field with it 3. Magnetic field lines “reconnect” and accelerate particles 4. Accelerated particles follow field lines to Earth Aurora Outer Radiation Belt Inner BeltEnergetic Particle Effects Spacecraft Systems: Energetic Particle Effects Spacecraft Systems Systems affected Spacecraft electronics Surface Charging and Discharge Single Event Upsets Deep Dielectric Charging Spacecraft imaging and attitude systems Polar Satellite Image Degradation SOHO Satellite Image Degradation Spacecraft Surface Charging (NASA animation) Energetic Particles Effects Radiation Hazard: Energetic Particles Effects Radiation Hazard Health Hazards from Energetic Particles Humans in space Space Shuttle, International Space Station, missions to Mars Crew/Passengers in high-flying jets Concorde carries radiation detectors Passengers and crew may receive radiation doses equivalent to many chest X rays. Ionosphere: Ionosphere The particles collide with the atmosphere and produce the Aurora and currents in the ionosphere As geomagnetic activity increases, the aurora gets brighter, more active, and moves away from the polar regions. Electric Power is affected Navigation Systems are affected Radio Communications are affected Image from NASA IMAGE SatelliteSlide21: Geomagnetic Storm Effects March 1989 Hydro Quebec Loses Electric Power for 9 Hours Transformer Damage Electric Power TransformerAurora: Aurora The particles spiral down the magnetic filed lines and collide with the atmosphere to produce the aurora. Colors indicate the atoms or molecules that are excited by the incoming particles Geomagnetic Storm Effects Aurora: Geomagnetic Storm Effects Aurora Intensity and location of the aurora depend on strength of storm Best time to view is around midnight No guarantee that aurora will occur G5 G3 G1 Photo by Jan Curtis, http://www.geo.mtu.edu/weather/auroraGeomagnetic Storms: Geomagnetic Storms Disrupt Radio Communications Impact Electric Power Systems Impact Satellites Disrupt Radio NavigationsSun to Earth: NASA Animation Sun to Earth An animation of a space weather event as it starts at the sun and end up at Earth Solar Flare Light Particles CME Magnetosphere Deflects the solar wind Responds to the disturbance Accelerates particles Ionosphere Accelerated particles collide with the atmosphere producing the auroraSpace Weather Storms Timing and Consequences: Space Weather Storms Timing and Consequences At T = 0, A Flare and CME Erupts on the Sun 8 Minutes later: First blast of EUV and X-Ray light increases the ionospheric density Radio transmissions are lost 30 min. to 24 hrs. later: Energetic Particles Arrive Astronauts are at risk Satellites are at risk High altitude aircraft crew are at risk 1 to 4 Days Later: CME Arrives and energizes the magnetosphere and ionosphere Electric Power is affected Navigation Systems are affected Radio Communications are affected Movie from NASA SOHO SatelliteWhat Controls the Size a Space Weather Storm?: What Controls the Size a Space Weather Storm? The Size of Flare or CME Big solar events tend to make big storms The Location of the flare site on the SUN If it is directed at Earth, it is more likely to make a storm If it toward the west side of the sun, the particles will arrive sooner The Direction of the Magnetic Field in the CME If the interplanetary magnetic field is southward, then there will likely be a big storm Note, there does not have to be a solar flare or CME to create a geomagnetic stormSpace Weather Scales: Space Weather Scales Three Categories Geomagnetic Storms (CMEs) Solar Radiation Storms (Particle Events) Radio Blackouts (Solar Flares) Combs RabinHow Often Do Space Weather Storms Occur?: How Often Do Space Weather Storms Occur? Solar Cycle is about 11 Years Radiation Storms 1-4 per month at max Geomagnetic Storms 3-5 per month at max Radio Blackouts 50-100 per month at max Sunspot Number 11-year cycle 1955 1960 1965 1970 1975 1980 1985 1990 1995 2000 Year Events Per Month Events Per Month Events Per MonthThe Solar Cycles of the Past: The Solar Cycles of the Past Sunspots have been recorded for the last 400 years Note that there were no sunspots for nearly 60 years after 1640 During the same period, it was very cold in Europe. This is a period called “The Little Ice Age” Is there a Connection? Recent studies say there may be Solar Maximum Solar MinimumSun and Climate: Sun and Climate The sun is the primary engine for weather and the climate Very large climate changes (Ice ages) are known to be caused by changes in insolation (amount and distribution of sunlight) The sun is likely responsible for some of the climate change… up to 1960s… but not the rapid increase in temperatures since then. NCAR Climate Model Ammann: SORCE 2003Primary Space Weather Satellites for SEC: NOAA POES NOAA GOES NASA ACE NASA SOHO L1 Primary Space Weather Satellites for SEC ACE Solar wind composition, speed, and direction Magnetic field strength and direction SOHO Solar EUV Images Solar Corona (CMEs) STEREO CME Direction and Shape Solar wind composition, speed, and direction Magnetic field strength and direction GOES Energetic Particles Magnetic Field Solar X-ray Flux Solar X-Ray Images POES High Energy Particles Total Energy Deposition Solar UV Flux NASA STEREO (Ahead) NASA STEREO (Behind) Events are observed on and near the sun No measurements until the Particles or CMEs are 99% of the way to Earth This provides only 30 minutes lead time for CMEs and no lead time for other eventsSummary: Summary Arrival 8 minutes 15 min. to 24 hrs. 1 to 4 days Time Radio Blackouts Bursts of X-ray and EUV radiation Radiation Storms Energetic Particles (electrons and protons) Geomagnetic Storms When the CME reaches Earth Systems Radio Comm. Satellites Power Companies Affected Airlines Astronauts Radio Comm. Radio Comm. Navigation (GPS) Satellite Drag Space Weather Storms come in three main categories Each category originates from different physical processes Each category arrives at a different speed Each category affects different users and technologies Space Weather Event You do not have the permission to view this presentation. In order to view it, please contact the author of the presentation.
SW Intro Viereck WoodRock Download Post to : URL : Related Presentations : Share Add to Flag Embed Email Send to Blogs and Networks Add to Channel Uploaded from authorPOINTLite Insert YouTube videos in PowerPont slides with aS Desktop Copy embed code: (To copy code, click on the text box) Embed: URL: Thumbnail: WordPress Embed Customize Embed The presentation is successfully added In Your Favorites. Views: 100 Category: Education License: All Rights Reserved Like it (1) Dislike it (0) Added: January 03, 2008 This Presentation is Public Favorites: 0 Presentation Description No description available. Comments Posting comment... Premium member Presentation Transcript Space Weather: What is it? How Will it Affect You? : Space Weather: What is it? How Will it Affect You? An introduction to Space Weather What is it? Where does it come from? What does it do? Rodney Viereck NOAA Space Environment Center Boulder ColoradoSpace Weather: What is it?: Space Weather: What is it? Space Weather refers to changes in the space environment near Earth Earth Sun Sun: Energy (386 Billion Billion MegaWatts) released in the form of… Light Particles (electrons and protons) Magnetic Field Activity Cycles 27 Days (solar rotation) ~100 Days Active Region Development 11 years 22 years 88 yearsGOES Solar X-Rays: GOES Solar X-Rays Space weather events are usually initiated by a solar flare or a coronal mass ejection During a solar flare, the x-ray irradiance can increase by several orders of magnitude in just a few minutesSpace Weather: What is it?: Space Weather refers to changes in the space environment near Earth Sun Interplanetary Space: Solar Wind Constant outflow from the sun Electrons and protons Disturbances from the sun produce waves and shocks in the solar wind Interplanetary Space Space Weather: What is it? EarthACE Solar Wind: ACE Solar Wind Solar Wind Density 1 to 100 particles per cm3 Speed 200 to 800 km/secSlide6: Space Weather refers to changes in the space environment near Earth Magnetosphere Magnetosphere: Created by Earth’s magnetic field Deformed by the Solar Wind Particles (electrons and protons) trapped on magnetic field lines Sun Interplanetary Space Space Weather: What is it? EarthGOES Particles and Magnetic Field: GOES Particles and Magnetic Field Protons Electrons Magnetic FieldSlide8: Space Weather refers to changes in the space environment near Earth Magnetosphere Sun Interplanetary Space Ionosphere Ionosphere: Layer of electrons at the top of the atmosphere (100 – 300 km up) Formed when extreme ultraviolet light from the sun hits Earth’s Atmosphere Strongly affected by changes in the magnetosphere Critical in the reflection and transmission of radio waves Space Weather: What is it? EarthPOES Ionospheric Particles: POES Ionospheric Particles Auroral Oval Electrons and Protons collide with the atmosphere The collisions excite atoms and molecules to produce the auroraOther Space Weather Terms: Other Space Weather Terms Solar Flare: An eruption on the sun that emits light (UV and x-rays) and often particles (electrons and protons). CME (Coronal Mass Ejection): A disturbance in the solar wind caused by an eruption on the sun. Solar Wind: The outward flow of electrons, protons, and magnetic field from the sun. Energetic Particles: electrons and protons that have been accelerated to high speeds. Geomagnetic Storm: The disturbance in the near-Earth particles and magnetic fields that can upset technological systems and creates aurora. Radiation Storm: A large flux of solar energetic protons as measured near Earth. Radio Blackout: An enhancement in the lower ionosphere as a result of large x-ray flares. Sequence Of Events: Sequence Of Events Active Region on the Sun Erupts Solar Flare (x-ray) Shock (energetic particles) Corornal Mass Ejection (particles and fields) X-rays reach Earth in 8 minutes (speed of light) Energetic Particles reach Earth in 15 min to 24 hours Coronal Mass Ejection reaches Earth in 1-4 DaysThree Types of Space Weather Storms: Three Types of Space Weather Storms Radio Blackouts Solar Flares send out x-rays Arrive at Earth in 8 minutes Modify the ionosphere Disrupt HF radio communication Impacts: Airline communication HF radio operators DoD Communications Satellite Communications Radiation Storms Solar Flares and Coronal Mass Ejections (CMEs) send out Energetic Particles Arrive at Earth in 15 minutes to 24 hours Modify the high latitude ionosphere Disrupt HF radio communication Impacts: Airline communication HF radio operators DoD Communications Ionizing radiation penetrates into the atmosphere Impacts: Astronauts (radiation) Satellite failures Geomagnetic Storms Coronal Mass Ejections (CMEs) send out Magnetic Clouds Arrive at Earth in 1-4 days Accelerate particles within the magnetosphere and into the ionosphere Impacts: HF radio communication Radio Navigation (GPS) Electric Power Grids Increased Satellite Drag AuroraThe Sun The Energy Source: The Sun The Energy Source The sun in X-rays From GOES 12 The Sun Rotates every 27 days Has an 11-year cycle of activity Flares produce large amounts of x-rays and extreme ultraviolet light but not much visible light An Erupting Prominence A Solar Flare Image from NASA TRACE Satellite Image from NASA SOHO SatelliteSolar Photons (Light): Solar Photons (Light) Visible light (small slow changes) Most of the energy output Impacts climate UV light (medium slow changes) Affects ozone production and loss EUV light (large changes) Affects radio communication Affects navigation Affects satellite orbits X-ray light (Can change by a factor of 1000 in five minutes) Affects radio communication Solar spectrum Solar variability Atmospheric penetration X-Ray Flare Variability (minutes) LeanProduct for Radio Operators: Product for Radio Operators TJFRCMEs (Coronal Mass Ejections) in Interplanetary Space: CMEs (Coronal Mass Ejections) in Interplanetary Space While Solar flares send out light (mostly x-rays) CMEs produce… Energetic particles Magnetic structures Propagate away from the sun but their paths are modified by the background solar wind and the sun’s magnetic field. Image from NASA SOHO Satellite Image from NASA SOHO SatelliteMagnetosphere: Magnetosphere What happens when a CME hits Earth? Solar wind is deflected around Earth Deflected solar wind drags Earth’s magnetic field with it Magnetic field lines “reconnect” and accelerate particles Accelerated particles follow field lines to Earth Aurora is produced when particles hit Earth’s atmosphere 1. Solar wind is deflected around Earth 2. Deflected solar wind drags Earth’s magnetic field with it 3. Magnetic field lines “reconnect” and accelerate particles 4. Accelerated particles follow field lines to Earth Aurora Outer Radiation Belt Inner BeltEnergetic Particle Effects Spacecraft Systems: Energetic Particle Effects Spacecraft Systems Systems affected Spacecraft electronics Surface Charging and Discharge Single Event Upsets Deep Dielectric Charging Spacecraft imaging and attitude systems Polar Satellite Image Degradation SOHO Satellite Image Degradation Spacecraft Surface Charging (NASA animation) Energetic Particles Effects Radiation Hazard: Energetic Particles Effects Radiation Hazard Health Hazards from Energetic Particles Humans in space Space Shuttle, International Space Station, missions to Mars Crew/Passengers in high-flying jets Concorde carries radiation detectors Passengers and crew may receive radiation doses equivalent to many chest X rays. Ionosphere: Ionosphere The particles collide with the atmosphere and produce the Aurora and currents in the ionosphere As geomagnetic activity increases, the aurora gets brighter, more active, and moves away from the polar regions. Electric Power is affected Navigation Systems are affected Radio Communications are affected Image from NASA IMAGE SatelliteSlide21: Geomagnetic Storm Effects March 1989 Hydro Quebec Loses Electric Power for 9 Hours Transformer Damage Electric Power TransformerAurora: Aurora The particles spiral down the magnetic filed lines and collide with the atmosphere to produce the aurora. Colors indicate the atoms or molecules that are excited by the incoming particles Geomagnetic Storm Effects Aurora: Geomagnetic Storm Effects Aurora Intensity and location of the aurora depend on strength of storm Best time to view is around midnight No guarantee that aurora will occur G5 G3 G1 Photo by Jan Curtis, http://www.geo.mtu.edu/weather/auroraGeomagnetic Storms: Geomagnetic Storms Disrupt Radio Communications Impact Electric Power Systems Impact Satellites Disrupt Radio NavigationsSun to Earth: NASA Animation Sun to Earth An animation of a space weather event as it starts at the sun and end up at Earth Solar Flare Light Particles CME Magnetosphere Deflects the solar wind Responds to the disturbance Accelerates particles Ionosphere Accelerated particles collide with the atmosphere producing the auroraSpace Weather Storms Timing and Consequences: Space Weather Storms Timing and Consequences At T = 0, A Flare and CME Erupts on the Sun 8 Minutes later: First blast of EUV and X-Ray light increases the ionospheric density Radio transmissions are lost 30 min. to 24 hrs. later: Energetic Particles Arrive Astronauts are at risk Satellites are at risk High altitude aircraft crew are at risk 1 to 4 Days Later: CME Arrives and energizes the magnetosphere and ionosphere Electric Power is affected Navigation Systems are affected Radio Communications are affected Movie from NASA SOHO SatelliteWhat Controls the Size a Space Weather Storm?: What Controls the Size a Space Weather Storm? The Size of Flare or CME Big solar events tend to make big storms The Location of the flare site on the SUN If it is directed at Earth, it is more likely to make a storm If it toward the west side of the sun, the particles will arrive sooner The Direction of the Magnetic Field in the CME If the interplanetary magnetic field is southward, then there will likely be a big storm Note, there does not have to be a solar flare or CME to create a geomagnetic stormSpace Weather Scales: Space Weather Scales Three Categories Geomagnetic Storms (CMEs) Solar Radiation Storms (Particle Events) Radio Blackouts (Solar Flares) Combs RabinHow Often Do Space Weather Storms Occur?: How Often Do Space Weather Storms Occur? Solar Cycle is about 11 Years Radiation Storms 1-4 per month at max Geomagnetic Storms 3-5 per month at max Radio Blackouts 50-100 per month at max Sunspot Number 11-year cycle 1955 1960 1965 1970 1975 1980 1985 1990 1995 2000 Year Events Per Month Events Per Month Events Per MonthThe Solar Cycles of the Past: The Solar Cycles of the Past Sunspots have been recorded for the last 400 years Note that there were no sunspots for nearly 60 years after 1640 During the same period, it was very cold in Europe. This is a period called “The Little Ice Age” Is there a Connection? Recent studies say there may be Solar Maximum Solar MinimumSun and Climate: Sun and Climate The sun is the primary engine for weather and the climate Very large climate changes (Ice ages) are known to be caused by changes in insolation (amount and distribution of sunlight) The sun is likely responsible for some of the climate change… up to 1960s… but not the rapid increase in temperatures since then. NCAR Climate Model Ammann: SORCE 2003Primary Space Weather Satellites for SEC: NOAA POES NOAA GOES NASA ACE NASA SOHO L1 Primary Space Weather Satellites for SEC ACE Solar wind composition, speed, and direction Magnetic field strength and direction SOHO Solar EUV Images Solar Corona (CMEs) STEREO CME Direction and Shape Solar wind composition, speed, and direction Magnetic field strength and direction GOES Energetic Particles Magnetic Field Solar X-ray Flux Solar X-Ray Images POES High Energy Particles Total Energy Deposition Solar UV Flux NASA STEREO (Ahead) NASA STEREO (Behind) Events are observed on and near the sun No measurements until the Particles or CMEs are 99% of the way to Earth This provides only 30 minutes lead time for CMEs and no lead time for other eventsSummary: Summary Arrival 8 minutes 15 min. to 24 hrs. 1 to 4 days Time Radio Blackouts Bursts of X-ray and EUV radiation Radiation Storms Energetic Particles (electrons and protons) Geomagnetic Storms When the CME reaches Earth Systems Radio Comm. Satellites Power Companies Affected Airlines Astronauts Radio Comm. Radio Comm. Navigation (GPS) Satellite Drag Space Weather Storms come in three main categories Each category originates from different physical processes Each category arrives at a different speed Each category affects different users and technologies Space Weather Event