A Meteorite Hit My House! How to Use a Neodymium Magnet to Find a Micrometeorite
It’s true. My home in Colorado was hit by a meteorite and I survived the impact. Okay, so maybe the meteorite was small in size… very small… so small you’d need a microscope to see it… but I was hit. Chances are your house has been hit by a few thousand micrometeorites, and you’ll be able to find a few if you know the secret place to look. The next time it rains, place a bucket under a drain spout in order to collect a good quantity of rain. Get rid of the leaves and roofing materials and then sift the remains through a bit of old window screen. What you’re after is so small that you’ll need a very strong magnet (neodymium magnet) to find them. Use this super-strong magnet to determine if any of the remaining particles contain iron. Those particles may be space dust, also known as micrometeorites.
Place the collected particles under a microscope – high power will be required to see them clearly. The micrometeorites will show signs of their fiery trip through the atmosphere — they will be rounded and may have small pits on their surfaces. Most meteorites falling through earth’s atmosphere will burn up before landing on earth, but some will reach the earth in microscopic sizes.
I recently ran across a fantastic article by Robert Beauford who is an expert in all things meteorite. The article steps you through the process of finding micrometeorites and the necessary background to create a killer science fair project.
Here’s part of the abstract…
Pieces of rock and metal frequently collide with Earth’s upper atmosphere. Most of these are no bigger than a golf ball but are traveling at tens of thousands of kilometers per hour. The atmosphere is very thin at this altitude of 80 to 100 kilometers (50 to 62 miles), however, it creates enough friction to cause these travelers from space to heat up to temperatures that make them burn brightly. These are the fireballs in the sky that are rightly called meteors, although they are often referred to as “shooting stars.”
Most meteors burn up completely in the atmosphere and never reach the ground. Those that survive the trip and reach the surface of Earth are called meteorites. While it is generally believed that meteorites are fairly rare, in reality about 30,000 tons of extraterrestrial material are deposited on Earth each year; bits of comets, chunks of asteroids, debris from the formation of our solar system more than four billion years ago. So why aren’t meteorites seen more often sitting on the ground? First of all, the largest portion of this material falls into the oceans, and secondly, most of the material that reaches the surface is microscopic, much too small to be noticed. These are the tiny specimens known as micrometeorites. As tons of micrometeorites fall each year, they gently land in our fields, on our homes, and on us.
One of the best places to study micrometeorites is Antarctica. In this isolated environment, very little earth-born debris falls, so any particles found on the clean South Pole ice have a greater likelihood of being extraterrestrial. In fact, what may be the largest collection of micrometeorites is in the hands of the Cold Regions Research and Engineering Laboratories.
Since most of us can’t arrange a field trip Antarctica, here is a way that you can collect micrometeorites in your hometown with the help of the rain. Micrometeorites fall everywhere, but collect very nicely on roofs. When rain falls, “space dust” is washed off the roof and through the downspouts. Position a deep bowl or bucket under a downspout. Many things will collect in your bucket; leaves, twigs, sands, etc. Collect this material from your bucket and dry it out. Remove the larger pieces of debris, such as leaves, and spread the remaining material on a sheet of paper (or plastic). Slowly run a strong neodymium magnet back and forth under the paper. (Note: Whenever using a neodymium magnet to collect particles, it’s always a good idea to place it in a plastic bag to keep it clean.) When you feel you have attracted most of the metallic particles, tilt the paper up so that the non-ferrous materials fall from the sheet.
Much of what you have collected will be Earth born debris. To find the micrometeorites you will need to examine the collected particles under a microscope. High power will be required to see them clearly. Look for particles that are rounded and may have small pits on their surface. This is evidence of a micrometeorite’s fiery trip through the atmosphere.
If you’re looking for something out of the ordinary for this year’s science fair project, check out Robert Beauford’s article and you’ll be on your way to a blue ribbon.