Studies on the ionospheric region during low solar activity in Brazil

Similar documents

A study of long-term climatology of ionospheric irregularities by using GPS phase fluctuations at the Brazilian longitudes

SPATIAL DISTRIBUTION OF NORTHERN HEMISPHERE WINTER TEMPERATURES OVER THE SOLAR CYCLE DURING THE LAST 130 YEARS

Solar Forcing of Electron and Ion Auroral Inputs

Referências Bibliográficas

Seasonal & Daily Temperatures. Seasons & Sun's Distance. Solstice & Equinox. Seasons & Solar Intensity

Solar Irradiance Variability

INTRODUCTION TO SOLAR WEATHER & HF PROPAGATION. Lewis Thompson W5IFQ September 27, 2011

The solar wind (in 90 minutes) Mathew Owens

Space Weather: An Introduction C. L. Waters. Centre for Space Physics University of Newcastle, Australia

ESCI 107/109 The Atmosphere Lesson 2 Solar and Terrestrial Radiation

The Effect of Space Weather Phenomena on Precise GNSS Applications

Ionosphere Properties and Behaviors - Part 2 By Marcel H. De Canck, ON5AU

Chapter 2: Solar Radiation and Seasons

Space Weather Prediction Research and Services for China Manned Space Mission

Satellite Measurements of Solar Spectral Irradiance

A Beginner s Guide to Space Weather and GPS Professor Paul M. Kintner, Jr. with acknowledgements to

Chapter Overview. Seasons. Earth s Seasons. Distribution of Solar Energy. Solar Energy on Earth. CHAPTER 6 Air-Sea Interaction

Solar Activity and Earth's Climate

Space Weather: Forecasting & Impacts on Critical Infrastructure

Solar Ast ro p h y s ics

8.1 Radio Emission from Solar System objects

Solar Irradiance Variability Observed During Solar Cycle 23

Solar Flux and Flux Density. Lecture 3: Global Energy Cycle. Solar Energy Incident On the Earth. Solar Flux Density Reaching Earth

EASA Safety Information Bulletin

WELCOME to Aurorae In the Solar System. J.E. Klemaszewski

R. Singh B. Veenadhari S. Alex Indian Institute of Geomagnetism, Navi Mumbai

Radiation Transfer in Environmental Science

- 1 - Jennifer McClure. To: env.essay@physics.org. From: Jennifer McClure (j.m.mcclure@student.liverpool.ac.uk)

Earth-Sun Relationships. The Reasons for the Seasons

Relationship between F2 layer critical frequency and solar activity indices during different solar epochs

Ionospheric Research with the LOFAR Telescope

ATM S 111, Global Warming: Understanding the Forecast

SPACE WEATHER SUPPORT FOR COMMUNICATIONS. Overview

SPACE WEATHER INTERPRETING THE WIND. Petra Vanlommel & Luciano Rodriguez

Heating & Cooling in Molecular Clouds

The Australian Ionosphere

Solar Energy. Outline. Solar radiation. What is light?-- Electromagnetic Radiation. Light - Electromagnetic wave spectrum. Electromagnetic Radiation

Sporadic E A Mystery Solved?

Homework #4 Solutions ASTR100: Introduction to Astronomy Fall 2009: Dr. Stacy McGaugh

Stratosphere-Troposphere Exchange in the Tropics. Masatomo Fujiwara Hokkaido University, Japan (14 March 2006)

CSSAR Space Science Cooperation

Blackbody radiation. Main Laws. Brightness temperature. 1. Concepts of a blackbody and thermodynamical equilibrium.

Ok, so if the Earth weren't tilted, we'd have a picture like the one shown below: 12 hours of daylight at all latitudes more insolation in the

The sun and the solar corona

Chapter 6: Cloud Development and Forms

Unusual declining phase of solar cycle 23: Weak semi-annual variations of auroral hemispheric power and geomagnetic activity

The Four Seasons. A Warm Up Exercise. A Warm Up Exercise. A Warm Up Exercise. The Moon s Phases

Simultaneous Heliospheric Imager and Interplanetary Scintillation observations of CMEs and CIRs

Corso di Fisica Te T cnica Ambientale Solar Radiation

Radiative effects of clouds, ice sheet and sea ice in the Antarctic

The Earth's Atmosphere. Layers of the Earth's Atmosphere

Overview of the IR channels and their applications

SELECTIVE GLAZING FOR SUN CONTROL

On Es-spread effects in the ionosphere connected to earthquakes

Operational experienced of an 8.64 kwp grid-connected PV array

How To Improve Energy Efficiency In Brazilian Buildings

CHAPTER 2 Energy and Earth

The Sun. Solar radiation (Sun Earth-Relationships) The Sun. The Sun. Our Sun

SOLAR ENERGY How much strikes the earth? How much can my building get? When is it too much?

8.5 Comparing Canadian Climates (Lab)

Sunlight and its Properties. EE 495/695 Y. Baghzouz

Solar Storms and Northern lights - how to predict Space Weather and the Aurora

Automatic Visualization Method of Height Time Development of Ionospheric Layers

RADIATION (SOLAR) Introduction. Solar Spectrum and Solar Constant. Distribution of Solar Insolation at the Top of the Atmosphere

Ay Fall The Sun. And The Birth of Neutrino Astronomy. This printout: Many pictures missing, in order to keep the file size reasonable

Activities of the Japanese Space Weather Forecast Center at Communications Research Laboratory

Introduction to Astronomy. Lecture 4: Our star, the Sun

Observing the Sun NEVER LOOK DIRECTLY AT THE SUN!!! Image taken from the SOHO web-site

Space Environment and Satellite Systems: Removing Clutter from Ground-to-Satellite Signals. Sigrid Close

Solar energy and the Earth s seasons

Multiple Choice Identify the choice that best completes the statement or answers the question.

2 Absorbing Solar Energy

Solar Wind: Theory. Parker s solar wind theory

Take away concepts. What is Energy? Solar Energy. EM Radiation. Properties of waves. Solar Radiation Emission and Absorption

Coronal Heating Problem

150 Watts. Solar Panel. one square meter. Watts

Solar Irradiance Reference Spectra (SIRS) for the 2008 Whole Heliosphere Interval (WHI)

Solar wind - atmospheric electricity - cloud microphysics connections to weather

The atmospheres of different planets

Heat Transfer. Energy from the Sun. Introduction

Optimum Solar Orientation: Miami, Florida

2. Orbits. FER-Zagreb, Satellite communication systems 2011/12

Seasonal Temperature Variations

Orbital-Scale Climate Change

Clouds and the Energy Cycle

The Sun: Our nearest star

Tropical Horticulture: Lecture 2

ATMOSPHERIC STRUCTURE. The vertical distribution of temperature, pressure,

Science Standard 4 Earth in Space Grade Level Expectations

Transcription:

Studies on the ionospheric region during low solar activity in Brazil Claudia M. N. Candido National Institute for Space Research - INPE Brazil 1

Plasma Bubbles-Spread-F OI 630.0-nm Peak at 250 km - F-layer bottomside OI 777.4-nm Peak at 350 km - F-layer peak OI 630,0 nm3 N OI 630,0 nm Univap O 21:57 LT 22:04 LT OI 777,4 nm OI 777,4 nm L 21:57 LT -512-256 0 S 256 512 Distância(km) 22:04 LT 2

OI 7774.0-nm - Fine structures 3

Altura (km) Distúrbios ionosféricos propagantes (TIDs Traveling ionospheric disturbances) 360 330 300 270 16-17 de JULHO de 1999 6.0 MHz 5.0 MHz 4.0 MHz 3.0 MHz 2.0 MHz 1.0 MHz 240 210 180 22 23 24 HORA LOCAL (h) 01 SPREAD-F 02 4

Solar minimum of the solar cycle 23-24 2008-2009 What happened? Previous solar minima 1966, 1976,1986, 1996 2006 Observed 2008 2 years later! Unusually deep and complex 266 spotless days in 2008 Magnetic field at the solar poles 40% weaker than previous solar cycles Lower UV radiation emission Lower solar flux Lower Total Solar Irradiance (TSU) Months with no sunspots August 2009 5

Sunspot area as a function of latitude and time Russel et al., Rev. Geop., 2010 6

Solar Indexes a) Images of the Sun at sunspot max and min b) Sunspots number c) F10.7 d) Mg-ii (280 nm) emission intensity e) Fs Open solar flux f) GCR (galactic cosmic rays) Antarctica g) TSI (total solar irradiance) PMOD h) Ap index Gray et al., Rev. Geop. 2010 7

Solar Indexes TSI : total Solar Irradiance (W.m 2 ) 10.7 cm solar flux vs solar SSN TSI Radiant energy emitted by the Sun at all wavelenghts crossing a square meter each second outside the Earth s atmosphere Hathaway, Living Rev. S. Phys., 2010 F10.7 10.7 cm solar flux is the disk integrated emission from the Sun at the =10.7 cm (2800 MHz) F 10.7 = 67+ 0.97R I + 17.6 (e -0.035RI -1 ) 8

Total Solar Irradiance TSI TSI was 0.2 Wm 2 lower than it was during the last minimum in 1996 (~22%) TSI is Earth s dominant energy input (10 4 > the next highest energy) Radiative forcing of climate Direct impact on sea surface temperatures and hydrological cycles Frohlich, C., A&A 501, L27 L30 (2009) 9

Galactic Cosmic Rays (GCR) Ionisation on lower atmosphere, Impact on electric field and on Condensation nuclei Steinhilber et al., PNAS, 2012 10

Forcing factor Total solar irradiance Solar UV irradiance Solar energetic particles Galactic cosmic rays Generic mechanism Radiative forcing of climate Direct impact on sea surface temperatures and hydrological cycle Heating the upper and middle atmosphere dynamic coupling down to troposphere. Middle and lower atmosphere chemistry and composition; impacts temperature and radiative forcing Ionization of upper and middle atmosphere, impact on composition and temperatures. ionospheretermosphere coupling Ionisation on lower atmosphere, impact on electric field and on condensation nuclei Haigh, Living Revies S. Phys., 2007 11

Solar Minimum Relevance Associated with lower surface temperatures in the Earth 17 th century Low temperatures Europe Low sunspot number Low solar activity Maunder minimum (Eddy, 1976) Total solar irradiance (TSI) Solar activity Earth s Climate 12

Gibson, JGR., 2009 13

Polar coronal hole smaller Polar magnetic flux 40% weaker Solar wind density decreased (45%) Solar wind velocity increased (13%) High relativistic electron flux which peaks a at 4-5 Earth radii (outer radiation belt) 3.4 times higher during the WHI High ocurrence of HSS HSS affect chemical, dynamics and energetics of the upper atmosphere Gibson, JGR., 2009 14

Heliospheric magnetic fields Ejection of Mass and energy Solar Maximum Strong and disorganized Higher ocurrence of CMEs e Solar flares Solar Minimum Weak and organized Higher ocurrence of Feixes rápidos (HSS) Sunspots number High Low or null Galactic Cosmic Rays in the Earth Shielded by CMEs Higher penetration 10 Be and 14 C Learn more about the Solar Dynamo Predict next solar cycles Influence of the Solar activity on Earth s climate Set instruments Coupling processes in the upper atmosphere Global dynamics processes 15

The ionosphere during the last two solar minimum over the Brazilian region Claudia M. N. Candido I. S. Batista INPE National Institute of Space Research Brazil 16

Solar Minima 1996-1997 and 2008-2009 Observations Low Latitude MSTIDs Post-Midnight F-region irregularities Spread-F in ionograms and Post midnight 5-m irregularities (RTI maps) Optical imaging Digisondes 30 MHz Coherent Backscatter Radar 17

Observation sites Sao Luis (44.2 W, 2.33 S, dip angle: 6.9 ) Fortaleza (38.45 W, 3.9 S, dip angle: 16 ) Cachoeira Paulista (23º S, 45º W, dip angle: -32) 18

Percentual de ocorrência (%) Low latitude Cachoeira Paulista 23º S, 45º W N EPBs Plasma Bubbles, Gravity waves and MSTIDs as seen by optical techniques over low latitude Cortesy by Dr. Abalde, Univap INPE S OI 630-nm GW Plasma bubbles vs. MSTIDs Climatology W E Sahai., JASTP, 2000 Airglow 34 32 30 28 26 24 22 20 18 16 14 12 10 8 6 4 2 0 1990 AAS 1995 BAS 1996 BAS 1997 AS_ASC 1998 AS_ASC 1999 AS_ASC 2000 AAS Média (AS_ASC + BAS) JAN FEV MAR ABR MAI JUN JUL MESES AGO SET OUT NOV DEZ Candido et al., GRL, 2008 Airglow data INPE S OI 557.7-nm MSTIDs OI 630.0-nm 19

Low latitude MSTIDs Solar minimum 1996 OI 630-nm emission All-sky imaging system Candido et al., GRL, 2008 20

Looking at the ionosphere during the solar minimum 2006! Low latitude MSTIDs and plasma irregularities/spread-f 21

Looking at the ionosphere in the solar minimum 2007! Depletions/MSTIDs Low latitude 22

Looking at the ionosphere in the solar minimum 2007! MSTIDs and spread-f/ irregularities 23

Looking at the ionosphere during the solar cycle 23/24! Post-Midnight irregularities a) Plasma bubbles (disturbed night) b) Plasma bubbles (quiet night) rare c) to f) meso-scale MSTIDs (quiet nights) JUNE SOLSTICE 24

Low Latitude Spread-F and Solar Flux (F10.7) Inverse Correlation Spread-F occurrence and Solar Flux Occurrence Peak at Solar Minimum Period June Solstice Pre-Midnight to Post- Midnight Candido et al., JGR, 2011 25

Equatorial Spread-F June solstice 2011 26

Images OI 630.0 nm Makela (Cajazeiras, Brazil) Ionospheric Parameters Digisondes São Luis (top panel) Fortaleza (bottom panel) 27

Equatorial Post-Midnight irregularities 2011 Candidoet al., JGR submitted Very distinct patterns of echoes/irregularities 28

Equatorial Ionosphere variability 29

Low latitude Ionosphere variability 30

Equatorial region - Sao Luis (44.2 W, 2.33 S, dip angle: 6.9 ) Summary hmf2 during 2009 was lower than during 1996, both day and night except during December solstice (Summer) fof2 (NmF2) didn t present remarkable differences PRE peak: occurred earlier in 2009 than in 1996 and was higher (22 % - December Solstice and 15 % Equinox) Low latitude region - Cachoeira paulista (23º S, 45º W, hmf2 and fof2 were higher in 1996 than in 2009 High ocurrence of plasma irregularities at low latitudes probably associated with mid-latitude processes MSTIDs Observation of meso-scale irregularities in both latitudes 31

Solar Minimum Solar Cycle 24 Next Solar Minimum Review Configuration, Calibration and/or Location of instruments Install new instruments 32

Acknowledgments To the technical and scientific Staff of INPE Brazil To Conselho Nacional de Desenvolvimento Científico e Tecnológico CNPq - for the partial financial support Proc. 503188/2011-5 To the organizers of the Escuela de ionosonda VIPIR em Jicamarca fot eht partial financial support To my family for the support 33