I read another article which asked strongly that people NOT use rare earth, neodimium or other strong magnets on meteorites, so this should perhaps be emphasized more strongly.
>>You say that your rock attracts a magnet or a compass. Most (>95%) of meteorites (irons and ordinary chondrites) attract cheap magnets because they contain iron-nickel metal. Many terrestrial rocks, however, contain the mineral magnetite, which also attracts a cheap magnet. (Do not use a rare-earth magnet; a cheap “refrigerator magnet” will attract a meteorite.)
The reason is that the strong magnets can re-orient the magnetic properties of the meteorite, ruining it for some aspects of tests or research. Seems polite to not ruin the thing for research for only a few seconds of 'that's cool' sensation.
To add: there's ongoing research to "reverse-engineer" the magnetic properties of certain meteorites that contain tetrataenite [0], which is as strong as a rare-earth magnet, but requires no rare-earths, but takes millions of years to make[1].
I studied techniques to speed this process up in the lab over a decade ago when this was new, and got to handle meteorites in the process.
A less "magnetically invasive" way to check if a material has magnetic material would be to put a compass nearby (as recommended by the site). Also, one could put a rare earth magnet on a string, watch it align to the earth's field away from the rock in question, then bring it carefully close to the meteorite seeing if it settles to a newer direction. This would still expose the meteorite to a magnet, but a very small field vs checking if something sticks.
Sounds like fun research and a quick skim seems to indicate success in fabrication - congrats! Did you get to the point of making magnets and if so, how strong did they get?
A friend (whom I shall not name) with the British Antarctic Survey once told me that the mornings after a meteor shower, they would take a Twin Otter plane out low, looking for dark rocks against the snow, land, gather, repeat, and finally sell the rocks on eBay.
Commenters didn't look at the chart to understand your question.
It's just a mistake in the chart.
"No" should point somewhere else to continue classifying. Also "someone" is ambiguous -- it could mean "someone nearby" (not meteorite) or "someone far away" (possibly meteorite).
I don't think it's a mistake - just a cheeky note that if you "saw it fall," you probably didn't. Your own link supports this.
> If you saw a meteor and later found a stone, then the stone is not a meteorite
> Meteorite fragments land far from where you last saw the meteor and there is no way that observers at a single point on the Earth’s surface are going to find fragments of the meteorite. It requires triangulation from several viewpoints, usually with cameras.
There are 365 degree cameras in every larger populated area. The people operating them report to a central database. I once saw a fireball going to the supermarket at night. It was in the database a couple hours later. It is like winning the powerball lottery if you would find a meteor not seen by anyone.
If you see a meteorite "fall" or something that looks like a shooting star, you aren't going to find it.
If it's moving fast enough to be a glowing streak, it's going to land hundreds of miles away from you. If it's near enough that you found it, you have no chance of seeing it land (sort of like seeing a bullet whizzing past your head).
Keep in mind that this flowchart is to cut down the number of people who contact this person wondering if their rock is a meteorite, which it almost always is not. I first learned about this chart from this: https://xkcd.com/1723/
>>You say that your rock attracts a magnet or a compass. Most (>95%) of meteorites (irons and ordinary chondrites) attract cheap magnets because they contain iron-nickel metal. Many terrestrial rocks, however, contain the mineral magnetite, which also attracts a cheap magnet. (Do not use a rare-earth magnet; a cheap “refrigerator magnet” will attract a meteorite.)
The reason is that the strong magnets can re-orient the magnetic properties of the meteorite, ruining it for some aspects of tests or research. Seems polite to not ruin the thing for research for only a few seconds of 'that's cool' sensation.