Presentation is loading. Please wait.

Presentation is loading. Please wait.

Goddard Space Flight Center Space Weather Workshop, April 2007, W. Dean Pesnell, GSFC 1 Why NASA Needs Solar Cycle Predictions W. Dean Pesnell NASA, Goddard.

Published by Modified over 8 years ago

Similar presentations

Presentation on theme: "Goddard Space Flight Center Space Weather Workshop, April 2007, W. Dean Pesnell, GSFC 1 Why NASA Needs Solar Cycle Predictions W. Dean Pesnell NASA, Goddard."— Presentation transcript:

1 Goddard Space Flight Center Space Weather Workshop, April 2007, W. Dean Pesnell, GSFC 1 Why NASA Needs Solar Cycle Predictions W. Dean Pesnell NASA, Goddard Space Flight Center Project Scientist, Solar Dynamics Observatory Member, Solar Cycle 24 Prediction Panel

2 Goddard Space Flight Center Space Weather Workshop, April 2007, W. Dean Pesnell, GSFC 2 NASA’s mandate is to build, fly, and operate spacecraft in the hostile environment of space. Our success comes from trying to understand what can go wrong and building and operating appropriate payloads. Things go right, things go worng, but the mandate is still there.

3 Goddard Space Flight Center Space Weather Workshop, April 2007, W. Dean Pesnell, GSFC 3 Solar Cycle Predictions are needed to Anticipate orbital decay and needs for reboosting Anticipate radiation exposure for upcoming missions

4 Goddard Space Flight Center Space Weather Workshop, April 2007, W. Dean Pesnell, GSFC 4 Solar Cycle Predictions are needed to Anticipate orbital decay and needs for reboosting Anticipate radiation exposure for upcoming missions Satisfy our scientific curiosity

5 Goddard Space Flight Center Space Weather Workshop, April 2007, W. Dean Pesnell, GSFC 5 Mission Operations must Understand Atmospheric Drag Drag affects every object in low-Earth Orbit Operating satellites may require boosting to stay in a usable orbit (ISS, Hubble)

6 Goddard Space Flight Center Space Weather Workshop, April 2007, W. Dean Pesnell, GSFC 6 Mission Operations must Understand Atmospheric Drag Large satellites without propulsion must be monitored to assure a safe re-entry (UARS) Knowledge of orbital debris is also required (rated as one of the biggest hazards to spaceflight)

7 Goddard Space Flight Center Space Weather Workshop, April 2007, W. Dean Pesnell, GSFC 7 Mission Planning must Allow for Atmospheric Drag Changes of the Jacchia model exospheric temperature with solar and geomagnetic activity. Mission planners must have some way to estimate future activity.

8 Goddard Space Flight Center Space Weather Workshop, April 2007, W. Dean Pesnell, GSFC 8 Radiation Hazards must be Understood to be Mitigated Radiation hazard is different for every orbit and duration –Incident particles range from cosmic rays to highly-relativistic electrons to solar protons Missions can have a 10-year leadtime, the Heliophysics Roadmap shows missions out to 2020! An understanding of the hazard in each of various study orbits may determine how the mission is designed Near-real-time knowledge of radiation hazard is also required –This requires short-term predictions of activity

9 Goddard Space Flight Center Space Weather Workshop, April 2007, W. Dean Pesnell, GSFC 9 Cosmic Rays and the Solar Cycle

10 Goddard Space Flight Center Space Weather Workshop, April 2007, W. Dean Pesnell, GSFC 10 Other Radiation Comes from the Sun and Magnetosphere A CME strikes the Earth’s magnetosphere. Both prompt (SEPs) and delayed (magnetospheric storms) radiation increases are possible.

11 Goddard Space Flight Center Space Weather Workshop, April 2007, W. Dean Pesnell, GSFC 11

12 Goddard Space Flight Center Space Weather Workshop, April 2007, W. Dean Pesnell, GSFC 12 Who Wouldn’t Want to Solve a Century-old Puzzle Flares and coronal mass ejections are the origins of space weather—but we still don’t know how to predict either! Simple timeseries analysis has not produced accurate predictions, additional information is required Solar activity comes from the dynamo within the convection zone and reaches out through the photosphere into the corona Many models of the solar dynamo exist but none are complete We have seen part of the solution: helioseismology and large-scale numerical models

13 Goddard Space Flight Center Space Weather Workshop, April 2007, W. Dean Pesnell, GSFC 13 Flows in the Solar Convection Zone These flows, which are being resolved by helioseismology, have been observed for one solar cycle. They constantly change with the cycle and may be the clue to the solar dynamo.

14 Goddard Space Flight Center Space Weather Workshop, April 2007, W. Dean Pesnell, GSFC 14 SDO, the first mission of Living With a Star, will provide the data needed to understand the solar convection zone and how magnetic field is assembled and dissipated in the solar atmosphere. The Solar Dynamics Observatory But that’s another story!

15 Goddard Space Flight Center Space Weather Workshop, April 2007, W. Dean Pesnell, GSFC 15 Questions?

16 Goddard Space Flight Center Space Weather Workshop, April 2007, W. Dean Pesnell, GSFC 16 Backup Slides Follow

17 Goddard Space Flight Center Space Weather Workshop, April 2007, W. Dean Pesnell, GSFC 17

18 Goddard Space Flight Center Space Weather Workshop, April 2007, W. Dean Pesnell, GSFC 18 Babcock-Leighton model Babcock-Leighton model

19 Goddard Space Flight Center Space Weather Workshop, April 2007, W. Dean Pesnell, GSFC 19

20 Goddard Space Flight Center Space Weather Workshop, April 2007, W. Dean Pesnell, GSFC 20

Download ppt "Goddard Space Flight Center Space Weather Workshop, April 2007, W. Dean Pesnell, GSFC 1 Why NASA Needs Solar Cycle Predictions W. Dean Pesnell NASA, Goddard."

Similar presentations

How Does the Sun Affect Earth? Unit 1 Key Concepts 6th Grade GEMS Space and Science Sequence.

How Does the Sun Affect Earth? Unit 1 Key Concepts 6th Grade GEMS Space and Science Sequence.
Solar Flares, CMEs, and Satellites, Oh My! M.M. Montgomery, PhD University of Central Florida LWS Heliophysics Summer School 2013.

Solar Flares, CMEs, and Satellites, Oh My! M.M. Montgomery, PhD University of Central Florida LWS Heliophysics Summer School 2013.
Stars and Galaxies The Sun.

Stars and Galaxies The Sun.
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.
 How Many Stars are in our Solar System???? a.Hundreds b.Millions c.Billions Explain why you chose the answer you picked.

 How Many Stars are in our Solar System???? a.Hundreds b.Millions c.Billions Explain why you chose the answer you picked.
The Sun Structure of the Sun & Solar Activity. Parts of the Sun Core: enormous pressure & high temperatures cause the fusion of hydrogen into helium.

The Sun Structure of the Sun & Solar Activity. Parts of the Sun Core: enormous pressure & high temperatures cause the fusion of hydrogen into helium.
Structure of the Sun & Solar Activity

Structure of the Sun & Solar Activity
CH. 29.2 – Solar Activity CH. 29 - MARQUES. Terms to know…  Sunspot  Prominence  Granules  solar flare  coronal mass ejection  aurora.

CH – Solar Activity CH MARQUES. Terms to know…  Sunspot  Prominence  Granules  solar flare  coronal mass ejection  aurora.
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.
NASA/NSTA Web Seminar: Living and Working in Space: Energy LIVE INTERACTIVE YOUR DESKTOP.

NASA/NSTA Web Seminar: Living and Working in Space: Energy LIVE INTERACTIVE YOUR DESKTOP.
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.
SDO Project Science Team 1 The Science of SDO. SDO Project Science Team 2 Sensing the Sun from Space  High-resolution Spectroscopy for Helioseismology.

SDO Project Science Team 1 The Science of SDO. SDO Project Science Team 2 Sensing the Sun from Space  High-resolution Spectroscopy for Helioseismology.
1.B – Solar Dynamo 1.C – Global Circulation 1.D – Irradiance Sources 1.H – Far-side Imaging 1.F – Solar Subsurface Weather 1.E – Coronal Magnetic Field.

1.B – Solar Dynamo 1.C – Global Circulation 1.D – Irradiance Sources 1.H – Far-side Imaging 1.F – Solar Subsurface Weather 1.E – Coronal Magnetic Field.
Space Environment I Introduction to Space Systems and Spacecraft Design Space Systems Design.

Space Environment I Introduction to Space Systems and Spacecraft Design Space Systems Design.
Conversations with the Earth Tom Burbine

Conversations with the Earth Tom Burbine
Space Weather W. Dean Pesnell, Shea Hess Webber and Emilie Drobnes SDO Project Science and E/PO Team Members July 2006.

Space Weather W. Dean Pesnell, Shea Hess Webber and Emilie Drobnes SDO Project Science and E/PO Team Members July 2006.
The Sun. Sun Considered a medium STAR 93,000,000 miles away from Earth 1.39 million kilometers in diameter (one million Earths can fit inside the sun.

The Sun. Sun Considered a medium STAR 93,000,000 miles away from Earth 1.39 million kilometers in diameter (one million Earths can fit inside the sun.
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.
EARTH & SPACE SCIENCE Chapter 29 The Sun 29.2 Solar Activity.

EARTH & SPACE SCIENCE Chapter 29 The Sun 29.2 Solar Activity.
The Sun a medium sized star 93,000,000 miles away 109 times diameter of Earth 1 million Earths could fit in the Sun Made of gas: 82% hydrogen, 17% helium,

The Sun a medium sized star 93,000,000 miles away 109 times diameter of Earth 1 million Earths could fit in the Sun Made of gas: 82% hydrogen, 17% helium,

Similar presentations

Ads by Google