That heat shield isn't always facing the direction the craft is going through, however, so it can't continually protect the sensitive inner body from any dust impacts, some of which can happen at an astonishing 10,800 kph (6,700 mph).

So what happens when that dust impacts the spacecraft? Usually, first, the grains vaporize, then ionize, which separates the ions and electrons that make up the atoms of the grain, resulting in a plasma. These plasmas themselves create a tiny explosion that lasts for only a thousandth of a second. Larger grains, however, can actually create debris. Some of that debris is made of vaporized dust, but some of it might be small parts of Parker itself blasted off by the dust grain.

There's another consequence of these impacts that are not as visible to the naked eye—they disturb the electromagnetic field around the probe. That disturbance is what Dr. David Malaspin of the Laboratory of Atmospheric and Space Physics at UCB is using to understand even more about Parker's local environment.

Since it is closer to the sun than any other artificial object, Parker is constantly bathed in the solar wind—a stream of plasma that emanates from the sun. Plasma is made up of electrically charged ions and electrons, so it also has an associated magnetic field. Any other introduced plasma, such as that resulting from the dust collisions with Parker, would impact that magnetic field.

Parker has its own suite of magnetically sensitive instruments to allow it to monitor the sun's magnetic field. But they are also helpful in detecting how the plasma created by Parker's collisions with dust is swept up with the solar wind. While that data does help understand some of the environmental conditions of the "zodiacal cloud"—a large dust cloud located near the sun—they could also be helpful in understanding how small-scale ionization processes anywhere interact with the solar wind. That can be particularly useful in modeling the interaction of Venus or Mars' atmosphere with the solar wind.

As part of that magnetic study, the researchers also looked at some of the debris that had been kicked off of the probe itself. In some instances, the debris situated itself in less than ideal positions—such as right in front of a navigational camera, causing a streak in the image or sunlight to reflect into it, and briefly disorienting the probe. For a mission like Parker, which must be constantly vigilant about its orientation lest it is fried by the sun, such disorientation could bring an end to the whole mission.

For now, Parker has a lot more mission to go. Its primary task goes until 2025, with another fifteen orbits around the sun planned on top of the nine it has already completed since its launch in 2018. Hopefully, it will be able to remain operational for the next four years while still holding onto the title of "most sand-blasted spacecraft" in addition to its other accolades.

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