Extreme Space Weather Events th June 2014 The Maunder minimum: An extreme space climate event? Mathew Owens, Mike Lockwood,

Slides:

Advertisements

Similar presentations

EMMREM Predicted Dose Rates for CRaTER N. Schwadron, L. Townsend, K. Kozarev, H. Spence, M. Golightly et al.

Advertisements

Uncovering the Global Slow Solar Wind Liang Zhao and Thomas H. Zurbuchen Department of Atmospheric, Oceanic and Space Sciences, University of Michigan.

Relating the Sub-Parker Spiral Structure of the Heliospheric Magnetic Field to the Dynamic Sources of Solar Wind N. A. Schwadron Southwest Research Institute.

An overview of the cycle variations in the solar corona Louise Harra UCL Department of Space and Climate Physics Mullard Space Science.

On the Space Weather Response of Coronal Mass Ejections and Their Sheath Regions Emilia Kilpua Department of Physics, University of Helsinki

An Analysis of Heliospheric Magnetic Field Flux Based on Sunspot Number from 1750 to Today and Prediction for the Coming Solar Minimum Introduction The.

29 April 2011Viereck: Space Weather Workshop 2011 The Recent Solar Minimum: How Low Was It? What Were The Consequences? Rodney Viereck NOAA Space Weather.

A New Look at the Heliosphere and Solar Modulation

The Independency of Stellar Mass-Loss Rates on Stellar X-ray Luminosity and Activity Space Telescope Science Institute – 2012.

The recent solar minimum How unprecedent is the Sun's behavior? Andrea Opitz CESR (CNRS-UPS) University of Toulouse, France University of Bern, 17th November.

Bastille Day 2000 Solar Energetic Particles Event: Ulysses observations at high heliographic latitudes M. Zhang Florida Institute of Technology.

IMPRS June Energetic particles in the solar system The heliosphere is flooded with those particles, from at least 6 different sources!

Solar particle events and their impact on stratospheric composition Miriam Sinnhuber Institut für Umweltphysik, Universität Bremen.

Synoptic maps and applications Yan Li Space Sciences Laboratory University of California, Berkeley, CA HMI team meeting, Jan 27, 2005, Stanford.

The Solar and Space Weather Reseach Group in Lund Space weather Solar activity - the driver Modelling and forecasting space weather and effects using KBN.

1 WSA Model and Forecasts Nick Arge Space Vehicles Directorate Air Force Research Laboratory.

Solar activity over the last 1150 years: does it correlate with climate? S.K. Solanki 1, I. Usoskin 2, M. Schüssler 1, K. Mursula 2 1: Max-Planck-Institut.

Absence of a Long Lasting Southward Displacement of the HCS Near the Minimum Preceding Solar Cycle 24 X. P. Zhao, J. T. Hoeksema and P. H. Scherrer Stanford.

Greenland / Atlantic blocking is a strong NAO- flow regime Woollings et al (2008, JAS; 2010, JCLIM)

1. Background2. Flux variation3. Polarity reversal4. Electron evolution5. Conclusions The role of coronal mass ejections in the solar cycle evolution of.

RT Modelling of CMEs Using WSA- ENLIL Cone Model

From Maunder Minimum to the recent Grand Solar Maximum 11:45 Tuesday November 18 auditorium Roger Session: 6. Key solar observables for assessing long-term.

Thomas Zurbuchen University of Michigan The Structure and Sources of the Solar Wind during the Solar Cycle.

Introduction to Space Weather Jie Zhang CSI 662 / PHYS 660 Spring, 2012 Copyright © The Sun: Magnetism Feb. 09, 2012.

1 Long-term Solar Synoptic Measurements with Implications for the Solar Cycle Leif Svalgaard Stanford University 23 April 2013.

1 Heliospheric Magnetic Field Leif Svalgaard Stanford University, CA

The Sun and the Heliosphere: some basic concepts…

Space Weather: Solar Wind Interactions with the Earth’s Magnetic field 24 October 2011 William J. Burke Air Force Research Laboratory/Space Vehicles Directorate.

The Sun. Solar Prominence 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.

1 C. “Nick” Arge Space Vehicles Directorate/Air Force Research Laboratory SHINE Workshop Aug. 2, 2007 Comparing the Observed and Modeled Global Heliospheric.

Katya Georgieva Boian Kirov Simeon Asenovski

Abstract Although Parker was the first to describe the solar wind successfully at the time, his elegant theory still masks a number of fundamental problems.

Climate Change- the way the Earth has constantly evolved and changed temperature throughout history.

Paper review Speaker ： Pei-Yu Chueh Adviser ： Yu-Heng Tseng Date ： 2011/3/22.

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

Introduction to Space Weather Jie Zhang CSI 662 / PHYS 660 Spring, 2012 Copyright © The Heliosphere: The Solar Wind March 01, 2012.

Conclusions Using the Diffusive Equilibrium Mapping Technique we have connected a starting point of a field line on the photosphere with its final location.

1 The Geo-Response to Extreme Solar Events: How Bad Can it Get? Leif Svalgaard Stanford University, California, USA AOGS,

Lecture 31: Historical Climate: Volcanoes and Sunspots

Fifty Years Of Solar Events NOAO 50 th Anniversary Symposium.

The Rise of Solar Cycle 24: Magnetic Fields from the Dynamo through the Photosphere and Corona and Connecting to the Heliosphere Part 2: Corona & Heliophere.

SOLAR VARIABILITY AND CLIMATE. HAS THE EARTH WARMED? Climatic Research Unit, UK.

Space Climate and the Recent Unusual Solar Minimum Sarah Gibson drawing upon results of IAU Symposium 286 Proceedings (and other recent publications)

Evolution of Magnetic Fields from the Sun’s Surface to the Heliopause of one Solar Cycle Nathan Schwadron, Boston University.

Solar Cycle Variation of the Heliospheric Magnetic Flux, Solar Wind Flux and Galactic Cosmic Rays Charles W. Smith, Nathan A. Schwadron Ken G. McCracken,

Webb, SMEI NASA, Sep05 NEW ENGLAND SPACE SCIENCE CONSORTIUM MEETING NO. 25 LOC:David Webb, ISR, Boston College;

Solar Magnetic Field Reversal V J Pizzo SHINE Workshop August 18, 2002.

CME Propagation CSI 769 / ASTR 769 Lect. 11, April 10 Spring 2008.

ORIGIN OF THE SLOW SOLAR WIND K. Fujiki ， T. Ohmi, M. Kojima, M. Tokumaru Solar-Terrestrial Environment Laboratory, Nagoya University and K. Hakamada Department.

WSM Whole Sun Month Sarah Gibson If the Sun is so quiet, why is the Earth still ringing?

Mike Lockwood (Southampton University & Space Science and Technology Department, STFC/Rutherford Appleton Laboratory ) Open solar flux and irradiance during.

1 ~130 Years of Solar Wind Data: The Floor and More E.W. Cliver Space Vehicles Directorate Air Force Research Laboratory AGU May 2008.

1 Global Warming –Beyond CO 2 : The Chilling Stars Henrik Svensmark, Center for Sun Climate Research Danish National Space Center Basel 2007.

Variability of the Heliospheric Magnetic Flux: ICME effects S. T. Lepri, T. H. Zurbuchen The University of Michigan Department of Atmospheric, Oceanic,

Reading Unit 31, 32, 51. The Sun The Sun is a huge ball of gas at the center of the solar system –1 million Earths would fit inside it! –Releases the.

Introduction to Space Weather Jie Zhang CSI 662 / PHYS 660 Fall, 2009 Copyright © The Heliosphere: Solar Wind Oct. 08, 2009.

Solar & Space Physics Decadal Survey Leading Principle: To make transformational scientific progress, the Sun, Earth, and heliosphere must be studied as.

1 Has the Sun’s Output Really Changed Significantly Since the Little Ice Age? Leif Svalgaard Stanford University, CA, USA

Solar Wind Helium Abundance and the Minimum Speed of the Solar Wind

What the Long-Term Sunspot Record Tells Us About Space Climate David H. Hathaway NASA/MSFC National Space Science and Technology Center Huntsville, AL,

Breakout Session F: Anomalous and Galactic Cosmic Rays Rick Leske and Maher Dayeh 5 presentations…and lots of discussion.

The heliospheric magnetic flux density through several solar cycles Géza Erdős (1) and André Balogh (2) (1) MTA Wigner FK RMI, Budapest, Hungary (2) Imperial.

Using the paleo-cosmic ray record to compare the solar activity during the sunspot minimum of with those during the Spoerer, Maunder, and Dalton.

Solar variability and its impact on climate Laura Balmaceda 4 th El Leoncito Solar Physics School November, 2008.

To what extent does solar variability contribute to climate change? Dr. David H. Hathaway NASA/Marshall Space Flight Center National Space Science and.

Evolution of the heliospheric magnetic field

SLIDE SHOW 6. SOLAR WIND (Mariner 2, 1962)

Solar cycle variation of the heliospheric magnetic field

MDI Global Field & Solar Wind

~130 Years of Solar Wind Data: The Floor and More

Presentation transcript:

Extreme Space Weather Events th June 2014 The Maunder minimum: An extreme space climate event? Mathew Owens, Mike Lockwood, Luke Barnard, Chris Scott and Ken McCracken The Maunder minimum: An extreme space climate event

2 Overview Direct observations –Sunspots –Aurora –Cosmogenic isotope abundance –Climate observations Reconstructions –Geomagnetic –Sunspot –Solar wind speed –Space weather implications

The Maunder minimum Eddy, Science, 1976 A period with: –An absence of sunspots –An (apparent) reduction in auroral activity –An (apparent) reduction in coronal structure during eclipses –A reduction in 14 C, suggesting increased cosmic ray flux –( 10 Be is now known to have increased, though still cycled) 3

Sunspot number Hoyt and Schatten, Sol Phys, 1998; Lessu et al, A&A, 2013; Svalgaard, IAU, 2011; Lockwood et al, JGR, Post 1750

Sunspot number: 11-year running means 5 Post 1750

Aurora e.g., Siscoe, Rev Geophys,

Cosmogenic isotope abundance Steinhilber et al., PNAS,

Heliospheric modulation potential Steinhilber et al., PNAS,

Climate records Manley, QJRMS, 1974, Lockwood et al., ERL, No “little ice age.”

Open Solar Flux, F S Flux threading the coronal source surface Unsigned Flux, F U =   |B R | r 2 cos(  ) d  d  r = heliocentric distance B R = radial field  = solar latitude  = solar longitude +  /2 2  -  /2 0 “closed” field line “open” field lines

Ulysses Balogh et al., 1995; Smith et al., 2001; Lockwood et al., 2000 ecliptic Ulysses showed that everywhere |B R |(d/R) 2 = |B RE | Thus total unsigned magnetic flux leaving the sun = 4  R 2 |B RE | |B RE | Earth R d |B R |

Geomagnetic reconstructions Lockwood et al., JGR, See also Svalgaard & Cliver, JGR,

Relation of F S and V SW Lockwood & Owens, JGR,

Relation of F S and V SW Lockwood & Owens, ApJ, 2014; Cliver & Ling, Sol Phys,

Before 1845: F S from R Solanki et al., Nature, 2000; Owens & Crooker, JGR, 2006 F S can be modelled as a continuity equation dF S /dt = S – L F S S ~ f CME ~ R 15

Loss of F S Sheeley & Wang, ApJ, 2001; Owens et al., JGR,

F S loss and the HCS tilt Owens and Lockwood, JGR,

F S reconstruction Owens and Lockwood, JGR, F S sourceF S loss

F S reconstruction Owens & Lockwood, JGR, 2012; Lockwood & Owens, JGR, Post 1750

F S reconstruction (11-year) Owens & Lockwood, JGR, 2012; Lockwood & Owens, JGR, Post 1750

Maunder minimum Owens, et al, GRL,

Modelling streamer belt width Schwadron et al., ApJ, 2010; Lockwood et al., JGR 2014 Separate streamer belt and coronal hole fluxes: –F S = F SB + F CH L = L SB + L CH Assume: –New flux is injected into the streamer belt –Streamer belt flux eventually becomes coronal hole flux Two coupled equations: –dF SB /dt = S - L SB F SB - S CH –dF CH /dt = S CH - L CH F CH Streamer belt half width = sin -1 [1-F CH /F S ] 22

Streamer belt width Owens et al., JGR See also Manoharan, JGR, M. Druckmuller

Streamer belt width Lockwood and Owens, JGR, Post 1750

Space weather “Great” geomagnetic storms, Greenwich observatory 25

Maunder minimum summary “Extremely” low (long term) solar magnetic field, compared to sunspot era and the last 10,000 years –Increased occurrence of cold winters, but no “little ice age” Reduced auroral frequency, –Difficult to quantify if this was “extreme” Polarity of the solar field continued to cycle Coronal holes were “extremely” small and the streamer belt was “extremely” broad –Slow solar wind at Earth. –No/weak CIRs? –Continued CME activity? 26

HCS location e.g., Smith el al., 2003; Owens & Forsyth, LRSP,

Computing the F S loss rate Owens and Lockwood, JGR,

PFSS solutions Magnetic field polarity at coronal source surface 29

Three-dimensional structure of interplanetary magnetic field Owens et al., JGR,

OCEANS STRATOSPHERE (  2/3) GALACTIC COSMIC RAYS BIOMASS TROPOSPHERE (  1/3) ICE SHEETS 10 Be + AEROSOL ( ~1 year) ( ~1 week) 14 C  1/2 = 5370 yr = 2 atoms cm -2 s Be  1/2 = 1.5×10 6 yr = atoms cm -2 s C & 10 Be: spallation products from O, N & Ar 14 C+0  14 C0 ; 14 C0+0H  14 C0 2 + H

ERA-40 Analysis of DJF temperatures & circulation (difference of high and low tercile subsets) ► sorted using open solar flux F S Low solar activity gives lower surface temperatures in central England Effect much stronger in central Europe Analysis shows a distinct system to NAO (Woollings et al, GRL.,2010; see also Barriopedro et al., JGR, 2008)

Space Challenges Central England Temperature (CET) Winter Means (DJF)  show upward drift  (linear) rate of rise dT ann /dt = 0.37  C c -1

Space Challenges Frost Fairs on the Thames  e.g. Winter 1683/4. Painted by Dutch artist Thomas Wijk ( )  N.B. notice how warm the next year was!

Space Challenges Frost Fairs on the Thames  The last one was 1813/14. Painted by Luke Clenell (1781 – 1840 )

Space Challenges Thames Freezing Over  N.B. in 1825 London Bridge demolished – acted as a salt water barrage  plus embankment increased flow rate

Space Challenges  1963 Thames at Windsor Thames Freezing Over