Sunday, March 13

blog 11: ALL ABOUT MAGNETISM!!!!1!!!1111etc

My assignment sheet says I'm supposed to blog about magnetism, so here I go. (Good of you to specify, Mrs. Chen.) I was going to talk about motors and car batteries, but... eh. Let's just do this.

another picture because it is required

oh look hello. it is my refrigerator. as you can see, we have many items posted on it by means of magic magnets. such items include winter ball photographs from i think last year and an announcement of birth from also last year and a report from my eye doctor and also a schedule for the chorus. there is also a christmas wreath that we put up i think in january and still haven't taken down.

on its own the refrigerator is not magnetized. if i were to hold a steel pin to it and let go the pin would fall to the floor and i would have to look for it for like twenty minutes or something because our kitchen floor has this weird pattern that makes finding small things triple hard. the magnets are, well, magnetic and also magnetized. they are permanent magnets and when they are on the refrigerator the bit of the refrigerator they are on is also magnetized.

So let's restore use of my shift key and talk a little more srsly about magnets, magnetism, and magnetizivitytyy. (I only said "a little more srsly.") As we're all aware, matter is made up of atoms (lit: "thingies"). Obviously I'm cutting corners here, but who cares? We got some subatomic particles, but the ones I'm interested in are electrons (lit: "negatively charged subatomic particles"). They are negatively charged! They also have spin (well, actually, it's more complicated than that, but let's just stay in kiddie land understanding. Deal? Good.) The spins of electrons mean they have their own little magnetic fields. In most materials, though, they come in pairs that cancel each other out. In magnetic materials (and here I am thinking mostly of ferromagnetic materials like my steel pins) the electron spins do not cancel, and we get domains. If a material doesn't have domains, then it isn't magnetic and it won't be magnetized no matter how you stroke it. Things like iron, nickel, and cobalt have domains. This doesn't mean that they are magnetized, though. If the domains are all willy-nilly, there's still no net magnetic field. However, it's possible to get the domains all lined up the same way (by, say for example off the top of my head, taking a magnet and stroking it in one direction). Once you do that, there is a net magnetic field. The temporary magnetic field and the permanent magnetic field attract each other, and the Winter Ball photographs stay up.