Press Release

MESSENGER Gets Closest Look at Solar-Flare Neutrons

By SpaceRef Editor
October 27, 2009
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MESSENGER Gets Closest Look at Solar-Flare Neutrons

On Dec. 31, 2007, the Sun awoke from the relatively quiescent period between Solar Cycles 23 and 24 to produce a solar flare that spewed high-energy neutrons into interplanetary space.

The Neutron Spectrometer flying aboard NASA’s MESSENGER spacecraft recorded the event, giving scientists a first-ever, up-close look at neutron production from a solar flare. In fact, it was the first time scientists detected solar neutrons at less than 1 AU from the Sun.

An AU is an Astronomical Unit, which is the average distance between the Earth and the Sun (about 93 million miles).

When the flare erupted, MESSENGER was flying at about half an AU, said William C. Feldman, a Senior Scientist at the Tucson-based Planetary Science Institute and lead author on a paper in the Journal of Geophysical Research, which includes an initial analysis of the data collected by MESSENGER during and after the flare. That paper is now in press and entitled “Evidence for Extended Acceleration of Solar Flare Ions from 1-8-MeV Solar Neutrons Detected with the MESSENGER Neutron Spectrometer.”

Feldman also is the Cognizant Co-Investigator for the Neutron Spectrometer, which is one of two sensors on MESSENGER’s Gamma-Ray and Neutron Spectrometer instrument.

For the first time, scientists were able to directly observe the neutron output from an average-sized solar flare, Feldman said. Previously, only the neutron bursts from the most powerful solar flares have been recorded on neutron spectrometers on Earth or in near-Earth orbit, he added. These bursts typically last about 50 to 60 seconds at the Sun.

“But we recorded neutrons from this flare over a period of six to ten hours,” Feldman said. “And what that’s telling us is that at least some moderate-sized flares continuously produce high-energy neutrons in the solar corona.”

“From this fact, we inferred the continuous production of protons in the 30-to-100-MeV (million electron volt) range due to the flare,” he added.

About 90 percent of all ions produced by a solar flare remain locked to the Sun on closed magnetic lines, but another population results from the decay of the neutrons near the Sun. This second population of decayed neutrons forms an extended seed population in interplanetary space that can be further accelerated by the massive shock waves produced by the flares, Feldman said.

“So the important results are that perhaps after many flare events two things may occur: continuous production of neutrons over an extended period of time and creation of seed populations of neutrons near the Sun that have decayed into protons,” he explained. “When coronal mass ejections (nuclear explosions in the corona) send shock waves into space, these feedstock protons are accelerated into interplanetary space.”

“There has always been the question of why some coronal mass ejections produce almost no energetic protons that reach the Earth, while others produce huge amounts,” he added. “It appears that these seed populations of energetic protons near the Sun could provide the answer, because it’s easier to accelerate a proton that already has an energy of 1 MeV than a proton that is at 1 keV (the solar wind).”

The seed populations are not evenly distributed, Feldman said. Sometimes they’re in the right place for the shock waves to send them toward Earth, while at other times they’re in locations where the protons are accelerated in directions that don’t take them near Earth.

The radiation produced by solar flares is of more than academic interest to NASA, Feldman added. Energetic protons from solar flares can damage Earth-orbiting satellites and endanger astronauts on the International Space Station or on missions to the Moon and Mars.

“People in the manned spaceflight program are very interested in being able to predict when a coronal mass ejection is going to be effective in generating dangerous levels of high-energy protons that produce a radiation hazard for astronauts,” he said. To do this, scientists need to know a lot more about the mechanisms that produce flares and which flare events are likely to be dangerous. At some point they hope to be able to predict space weather — where precipitation is in the form of radiation — with the same accuracy that forecasters predict rain or snow on Earth.

MESSENGER could provide significant data toward this goal, Feldman observed. “What we saw and published is what we hope will be the first of many flares we’ll be able to follow through 2012,” he said. “The beauty of MESSENGER is that it’s going to be active from the minimum to the maximum solar activity during Solar Cycle 24, allowing us to observe the rise of a solar cycle much closer to the Sun than ever before.”

MESSENGER is currently orbiting the Sun between 0.3 and 0.6 AU on its way to orbit insertion around Mercury in March 2011. At Mercury, it will be within 0.45 AU of the Sun for one Earth year.

The Johns Hopkins University Applied Physics Laboratory built and operates the MESSENGER spacecraft and manages this Discovery-class mission for NASA.

The Planetary Science Institute

The Planetary Science Institute ( is a private, nonprofit 501(c)(3) corporation dedicated to solar system exploration. It is headquartered in Tucson, Arizona, where it was founded in 1972.

PSI scientists are involved in numerous NASA and international missions, the study of Mars and other planets, the Moon, asteroids, comets, interplanetary dust, impact physics, the origin of the solar system, extra-solar planet formation, dynamics, the rise of life, and other areas of research. They conduct fieldwork in North America, Australia and Africa. They also are actively involved in science education and public outreach through school programs, children’s books, popular science books and art.

PSI scientists are based in 16 states, the United Kingdom, France, Switzerland, Russia and Australia.

SpaceRef staff editor.