Presentation is loading. Please wait.

Presentation is loading. Please wait.

Mike Lockwood STFC/Rutherford Appleton Laboratory & Southampton University Our life-giving star: the flow of energy from the Sun to the Earth BA Festival.

Published byShaylee Knotts Modified over 9 years ago

Similar presentations

Presentation on theme: "Mike Lockwood STFC/Rutherford Appleton Laboratory & Southampton University Our life-giving star: the flow of energy from the Sun to the Earth BA Festival."— Presentation transcript:

1 Mike Lockwood STFC/Rutherford Appleton Laboratory & Southampton University Our life-giving star: the flow of energy from the Sun to the Earth BA Festival of Science, York, Monday 10 th September 2007 How the Sun Influences Modern Life

2 Galactic Cosmic Rays Solar Energetic Particles Satellite Damage Human Spaceflight Hazards Sun and Climate Change

3 How the Sun Influences Modern Life Galactic Cosmic Rays Solar Energetic Particles Satellite Damage Human Spaceflight Hazards Sun and Climate Change

4 The Solar Wind Plasma A Coronograph is a man-made eclipse with an occulting disc blocking out the visible surface of the Sun (the Photosphere). Allows us to observe the hot solar atmosphere, the Corona Continuous outflow of ionised gas (“plasma”), The Solar Wind,  10 14 kg per day Events CMEs eject ~10 13 kg at about 350 km s -1 (PS watch the comet!)

5 The “Frozen-in flux” Theorem Charged particle motions Magnetic Field B ( by definition of B ) Lorentz Force B B

6 Emergence of Coronal Magnetic Flux Loops of magnetic flux emerge through the surface in active (sunspot) regions Some of this flux is “open” rises through the corona and is frozen-in to the solar wind outflow

7 Parker Spiral (an example of frozen-in) Sun Solar wind flow is radial  Solar rotation and radial solar wind generates a Parker spiral field structure  Field is “frozen-in” to the solar wind flow

8 Sun Solar wind flow is radial  Solar rotation and radial solar wind generates a Parker spiral field structure  Field is “frozen-in” to the solar wind flow Parker Spiral (an example of frozen-in)

9 Sun Solar wind flow is radial  Solar rotation and radial solar wind generates a Parker spiral field structure  Field is “frozen-in” to the solar wind flow Parker Spiral (an example of frozen-in)

10 Sun Solar wind flow is radial  Solar rotation and radial solar wind generates a Parker spiral field structure  Field is “frozen-in” to the solar wind flow Parker Spiral (an example of frozen-in)

11 Sun Solar wind flow is radial  Solar rotation and radial solar wind generates a Parker spiral field structure  Field is “frozen-in” to the solar wind flow Parker Spiral (an example of frozen-in)

12 Sun Solar wind flow is radial  Solar rotation and radial solar wind generates a Parker spiral field structure  Field is “frozen-in” to the solar wind flow Parker Spiral (an example of frozen-in)

13 Sun Solar wind flow is radial  Solar rotation and radial solar wind generates a Parker spiral field structure  Field is “frozen-in” to the solar wind flow Parker Spiral (an example of frozen-in)

14 Sun Solar wind flow is radial  Solar rotation and radial solar wind generates a Parker spiral field structure  Field is “frozen-in” to the solar wind flow Parker Spiral (an example of frozen-in)

15 Sun Solar wind flow is radial  Solar rotation and radial solar wind generates a Parker spiral field structure  Field is “frozen-in” to the solar wind flow Parker Spiral (an example of frozen-in)

16 Sun Solar wind flow is radial  Solar rotation and radial solar wind generates a Parker spiral field structure  Field is “frozen-in” to the solar wind flow Parker Spiral (an example of frozen-in)

17 Sun Solar wind flow is radial  Solar rotation and radial solar wind generates a Parker spiral field structure  Field is “frozen-in” to the solar wind flow Parker Spiral (an example of frozen-in)

18  Interplanetary scintillation is the “twinkling” if radio stars caused by irregularities in the solar wind  Tomographic reconstruction from interplanetary scintillations  Solar rotation and radial solar wind generates a Parker spiral field structure  Co-rotates with the solar corona (every 27 days in Earth’s frame) Parker Spiral (an example of frozen-in)

19 A Stellar Heliosphere interstellar wind bow shock heliopause heliosheath  Hubble observations of the heliosheath behind the bow shock where the heliosphere of LL Ori heliosphere meets its (dense) local interstellar wind in the Orion nebula

20 Galactic Cosmic Rays The coronal source flux is dragged out by the solar wind flow to give the heliospheric field which shields Earth from galactic cosmic rays

21 Cosmic Rays Anticorrelation with sunspot numbers Sunspot Number Huancauyo – Hawaii neutron monitor counts (>13GV) Climax neutron monitor counts (>3GV)

22 A Stellar Heliosphere Cosmic ray tracks in a bubble chamber

23 How the Sun Influences Modern Life Galactic Cosmic Rays Solar Energetic Particles Satellite Damage Human Spaceflight Hazards Sun and Climate Change

24 Solar Energetic Protons (SEPs)  Energised at the shock fronts of CMEs (and CIRs)  Follow heliospheric field lines  Seen here striking the imager CCD plate of the LASCO coronograph on the SoHO spacecraft

25 Sun Parker Spiral (an example of frozen-in)

26 Sun  SEPs generated at front of CMEs  Guided along IMF Parker Spiral (an example of frozen-in) CME

27 How the Sun Influences Modern Life Galactic Cosmic Rays Solar Energetic Particles Satellite Damage Human Spaceflight Hazards Sun and Climate Change

28 Spacecraft Damage spacecraft penetrating radiation electronics box sensitive component charge buried in insulator can discharge floating circuit trace can collect charge and discharge radiation environment damage:  Surface charging  0.1 – 100 keV electrons  Single event upsets  MeV ions  Cumulative radiation dose  Limits spacecraft lifetime  Internal charging (“deep dielectric charging”)  MeV electrons

29  Tomographic reconstruction from interplanetary scintillations The Bastille Day Storm CMEs seen by IPS

30 ► Ground-level enhancement (GLE) of solar energetic particles seen between Forbush decreases of galactic cosmic rays caused by shielding by the two CMEs ► Here seen at stations in both poles (McMurdo and Thule) Neutron Monitor counts Forbush decrease caused by 1 st CME GLE Forbush decrease caused by CME associated with GLE nm counts The Bastille Day Storm GCRs and SEPs

31  ▲▼ = Single event upsets (SEUs) suffered by satellites in geostationary and high altitude orbits  several satellites were powered down to protect them The Bastille Day Storm SEPs seen at Geostationary Orbit

32 How the Sun Influences Modern Life Galactic Cosmic Rays Solar Energetic Particles Satellite Damage Human Spaceflight Hazards Sun and Climate Change

33 BIOLOGICAL EFFECTS Heavy ions breaks molecular links & can cause nuclear reactions so (e.g.) C converted to N and O in molecules

34 The Apollo Missions

35 Above annual dose SEPs: just how lucky were the lunar astronauts?  SEPs during the era of the Apollo Missions Raised cancer risk Severe radiation sickness Severe radiation sickness Instantly fatal Average annual dose at Earth’s surface Max. annual dose for a radiation worker

36 SEPs: what’s the space weather been like? Above annual dose Raised cancer risk Severe radiation sickness Instantly fatal  SEPs and Galactic cosmic rays since the Apollo Missions

37 How the Sun Influences Modern Life Galactic Cosmic Rays Solar Energetic Particles Satellite Damage Human Spaceflight Hazards Sun and Climate Change

38 Total Solar Irradiance  best composite of observations (by PMOD, Davos)  shows 0.1% solar cycle variation  damped out by large thermal capacity of Earth’s oceans  but are there century- scale changes which would not be damped?

39 Total solar irradiance changes and magnetic field emergence  Dark sunspots and bright faculae are where magnetic field threads the solar surface

40 TSI reconstructions  Open Solar Flux, F S  TSI (for 3 assumptions for the Maunder Minimum) A. [F p ] MM = [F p ] now B. [F p ] MM = 0 C. [F p ] MM = [F p ] now /2

41 Recent trends - revealed by averaging over solar cycle length, L ► sunspot number, R ► F S from IMF data ► GCR counts C (Climax n.m.) ► PMOD composite of TSI data ► solar cycle length, L running mean over T=[9:(1/4):13] yrs running mean over T=L yrs

42

Download ppt "Mike Lockwood STFC/Rutherford Appleton Laboratory & Southampton University Our life-giving star: the flow of energy from the Sun to the Earth BA Festival."

Similar presentations

The Solar Wind and Heliosphere (with a space weather emphasis!) V J Pizzo (NOAA/SEC)

The Solar Wind and Heliosphere (with a space weather emphasis!) V J Pizzo (NOAA/SEC)
Chapter 10 Our Star. 10.1 A Closer Look at the Sun Our Goals for Learning Why does the Sun shine? What is the Sun’s structure?

Chapter 10 Our Star A Closer Look at the Sun Our Goals for Learning Why does the Sun shine? What is the Sun’s structure?
Solar Theory (MT 4510) Clare E Parnell School of Mathematics and Statistics.

Solar Theory (MT 4510) Clare E Parnell School of Mathematics and Statistics.
ACTIVITY ON THE SUN: Prominences Sunspots Solar Flares CME’s – Coronal Mass Ejections Solar Wind Space Weather.

ACTIVITY ON THE SUN: Prominences Sunspots Solar Flares CME’s – Coronal Mass Ejections Solar Wind Space Weather.
Chapter 8 The Sun – Our Star.

Chapter 8 The Sun – Our Star.
The Sun – Our Star Chapter 7:. General Properties Average star Absolute visual magnitude = 4.83 (magnitude if it were at a distance of 32.6 light years)

The Sun – Our Star Chapter 7:. General Properties Average star Absolute visual magnitude = 4.83 (magnitude if it were at a distance of 32.6 light years)
Space Weather Causes and Consequences An introduction to Space Weather What is it? Where does it come from? Who is impacted? Rodney Viereck NOAA Space.

Space Weather Causes and Consequences An introduction to Space Weather What is it? Where does it come from? Who is impacted? Rodney Viereck NOAA Space.
Cosmic rays in solar system By: Tiva Sharifi. Cosmic ray The earth atmosphere is bombarded with the energetic particles originating from the outer space.

Cosmic rays in solar system By: Tiva Sharifi. Cosmic ray The earth atmosphere is bombarded with the energetic particles originating from the outer space.
IMPRS June 2003. Energetic particles in the solar system The heliosphere is flooded with those particles, from at least 6 different sources!

IMPRS June Energetic particles in the solar system The heliosphere is flooded with those particles, from at least 6 different sources!
Lecture 2 Humans and Space Weather. When high energy particles encounter atoms or molecules within the human body, ionization may occur. –Ionization can.

Lecture 2 Humans and Space Weather. When high energy particles encounter atoms or molecules within the human body, ionization may occur. –Ionization can.
SPACE WEATHER Definition used by the US National Space Weather Plan: Conditions on the Sun and the solar wind, magnetosphere, ionosphere, and thermosphere.

SPACE WEATHER Definition used by the US National Space Weather Plan: Conditions on the Sun and the solar wind, magnetosphere, ionosphere, and thermosphere.
7 THE SUN The star we see by day. 7 Goals Summarize the overall properties of the Sun. What are the different parts of the Sun? Where does the light we.

7 THE SUN The star we see by day. 7 Goals Summarize the overall properties of the Sun. What are the different parts of the Sun? Where does the light we.
Chapter 7 The Sun. Solar Prominence – photo by SOHO spacecraft from the Astronomy Picture of the Day site link.

Chapter 7 The Sun. Solar Prominence – photo by SOHO spacecraft from the Astronomy Picture of the Day site link.
From Geo- to Heliophysical Year: Results of CORONAS-F Space Mission International Conference «50 Years of International Geophysical Year and Electronic.

From Geo- to Heliophysical Year: Results of CORONAS-F Space Mission International Conference «50 Years of International Geophysical Year and Electronic.
The Sun The Sun in X-rays over several years The Sun is a star: a shining ball of gas powered by nuclear fusion. Luminosity of Sun = 4 x 10 33 erg/s =

The Sun The Sun in X-rays over several years The Sun is a star: a shining ball of gas powered by nuclear fusion. Luminosity of Sun = 4 x erg/s =
Solar Energetic Particles -acceleration and observations- (Two approaches at the highest energy) Takashi SAKO Solar-Terrestrial Environment Laboratory,

Solar Energetic Particles -acceleration and observations- (Two approaches at the highest energy) Takashi SAKO Solar-Terrestrial Environment Laboratory,
Conversations with the Earth Tom Burbine

Conversations with the Earth Tom Burbine
The Dangers of Solar Storms and Solar Cycles.  For every 1 million atoms of hydrogen in the entire sun  98,000 atoms of helium  850 of oxygen  360.

The Dangers of Solar Storms and Solar Cycles.  For every 1 million atoms of hydrogen in the entire sun  98,000 atoms of helium  850 of oxygen  360.
Astronomy 1020 Stellar Astronomy Spring_2015 Day-30.

Astronomy 1020 Stellar Astronomy Spring_2015 Day-30.
The Sun and the Heliosphere: some basic concepts…

The Sun and the Heliosphere: some basic concepts…

Similar presentations

Ads by Google