QUESTION: I was wondering; how will or did the radiation belt of Jupiter affect the orbiter and the probe? ANSWER from Steven Tyler on February 20, 1996: Thank you for your question. When Galileo first became a project, nearly 20 years ago, many of us wondered what would happen in the Jupiter radiation belts. We did not have much information. Pioneer had shown that there might be some intense radiation, and Voyager had not yet reached Jupiter. However, in 1979 both Voyagers reached Jupiter and we found out a little more. What we discovered were three threats to our craft. First, there was a "total dose" threat of low-energy particles. This was a lot like the threat to a person. A big dose would be bad...a bigger dose even worse. Different parts would react differently to large radiation doses, and would begin to fail. Galileo was planning to travel to within 3 Jupiter radii of the surface, and the doses we were seeing indicated that after a couple of orbits, we would be in serious trouble. We decided to solve this problem by raising our minimum distance from Jupiter after the first orbit. We'd come no closer than seven to ten Jupiter radii from the cloud tops on the later orbits, and greatly increase the lifetime of the Orbiter. The second threat was from higher energy particles. These were often highly charged nuclei of Oxygen and Sulfur. These often moved with just the right speed to go straight through the wall of our craft and deposit plenty of energy in one of Galileo's memory chips or registers. The problem was that Galileo's computers run on electricity, and a single ion would supply enough electricity to change a setting in the computer. We began to worry about the craft mysteriously following some unintended command after being hit by a stray ion. We did not have enough information about the Jupiter environment to be sure how safe we would be. We finally decided to avoid unnecessary risk, so we shielded the most sensitive computer parts. It was expensive, but it provided some critical protection. The third threat was that the radiation belt particles would charge up our craft so much that electric arcs (like little lightning bolts) would begin to appear inside the craft, shorting out some of the equipment or possibly causing unintended firing of bolts or squibs. This would wreak havoc on Galileo, so we avoided it by shielding key circuits. When Galileo finally got to Jupiter, many of us wondered whether or not one or more stray ions would get through to the on-board computers. As it turned out, we had no problems; none of the bits were changed by the high-energy ions. Nor did we have any serious problems from short circuits. But how much total radiation did we absorb? We're still not sure. As we approached Io, we expected to be hit by quite a few particles (mostly electrons). But we did not get hit by anywhere near as many as we feared. After we reached Io, the total dose seems to have gone way up. When we added it all up, it seemed that we came close to getting the dose we expected. Our maneuver to raise the perijove (the minimum distance we are from Jupiter in our orbit) is scheduled for March 14, and after this we'll be much safer. Without that maneuver, it looks like one more orbit would give us a fatal radiation dose. The good news is that the Orbiter does not seem to be suffering from any obvious symptoms of radiation poisoning. It's still possible that our craft may last longer than we originally expected in this radiation environment. The Probe spent a shorter time in the radiation environment and made some measurements of it. The Probe lasted only about an hour after entering Jupiter's atmosphere, and I don't know of any signs of radiation damage to it. Heat and pressure and battery lifetime should fully explain the loss of the Probe's signal (the Probe went to twice the pressure it was required to reach before the signal stopped). We're still looking at Probe data, and some radiation effect may turn up.