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The Solar Maximum Mission

THE SUN 

Why We Study the Sun 
The Big Questions 
Magnetism - The Key 

SOLAR STRUCTURE 

The Interior 
The Photosphere 
The Chromosphere 
The Transition Region 
The Corona 
The Solar Wind 
The Heliosphere 

SOLAR FEATURES 

Photospheric Features 
Chromospheric Features 
Coronal Features 
Solar Wind Features 

THE SUN IN ACTION 

The Sunspot Cycle 
Solar Flares 
Post Flare Loops 
Coronal Mass Ejections 
Surface and Interior Flows 
Waves and Helioseismology 

RESEARCH AREAS 

Flare Mechanisms 
3D Magnetic Fields 
The Solar Dynamo 
Sunspot Cycle Predictions 
Coronal Heating 
Solar Wind Dynamics 

PREVIOUS PROJECTS 

The Skylab Mission 
The Solar Maximum Mission 
The SpaceLab 2 Mission 
MSSTA 

CURRENT PROJECTS 

MSFC TVM  
MSFC EXVM  
The Yohkoh Mission 
The Ulysses Mission 
The SOHO Mission 
The GONG Project 
The Sun in Time (EPO) 

FUTURE PROJECTS 

The Solar B Mission 
The GOES SXI Instruments 
Interstellar Probe  

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The Solar Maximum Mission (SMM or SolarMax) was launched on February 14, 1980. It carried several scientific instruments which provided new insights into the nature of solar flares. The spacecraft was rescued and repaired by a 1984 Space Shuttle Challenger mission. This rescue and repair of SMM, (153 kb GIF image) , (124 kb GIF image) , (133 kb GIF image) , extended the useful lifetime of the mission to allow for better coverage of the solar activity cycle. SMM reentered the Earth's atmosphere and burned-up on December 2, 1989.

SMM carried a battery of instruments designed to study solar flares and the active solar atmosphere. These instruments included the Ultraviolet Spectrometer and Polarimeter (UVSP), the Active Cavity Radiometer Irradiance Monitor (ACRIM), the Gamma-Ray Spectrometer (GRS), the Hard X-Ray Burst Spectrometer (HXRBS), the soft X-Ray Polychromator (XRP), and the Hard X-ray Imaging Spectrometer (HXIS). Several members of the MSFC Solar Physics Group were involved with UVSP under the direction of  Dr. Einar Tandberg-Hanssen.

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The ACRIM instrument package monitored the total energy output of the Sun (often referred to as the "Solar Constant") throughout the mission with great precision. These observation showed the expected dimming of the Sun when sunspots rotated into view and provided important information on the extent of this dimming. More importantly, however, ACRIM showed that the Sun is actually brighter during the maximum of the sunspot cycle when more spots are observed on the Sun's surface. Although the sunspots themselves are dark and produce dimming, they are surrounded by faculae that are bright and, on average, more than offset the dimming due to the sunspots.

The HXIS instrument obtained images over small areas of the sun within six energy bands from 3.5 to 30 keV (3.5 to 0.4Å). The central part of the images had a spatial resolution of 8 arc-seconds. The normal time resolution was about 8 seconds but some flare observations were obtained with 1.5 second time intervals. HXIS observations showed that energetic X-rays are emitted from the footpoints of the magnetic loops seen in solar flares. HXIS showed that large coronal loops with temperatures up to 10 million degrees Kelvin are probably always present in the corona. HXIS also found that X-rays are often seen from widely separated point prior to the onset of a coronal mass ejection.

Web Links
Solar Maximim Mission - NASA/Goddard SMM resources

Solar Maximim Mission - NASA/JPL SMM resources

 

Author: David H. Hathaway, david.hathaway@msfc.nasa.gov, (256) 544-7610
Mail Code SD50, NASA/Marshall Space Flight Center, Huntsville, AL 35812

 

Responsible Official: John M. Davis, john.m.davis@msfc.nasa.gov, (256) 544-7600
Mail Code SD50, NASA/Marshall Space Flight Center, Huntsville, AL 35812

 

Last revised 2000 January 07 - D. H. Hathaway