Frankly, the title of this chapter is a bit ambitious. Before you can do much that’s very interesting with electronics, you need to have a basic understanding of what electricity is and how it works, but unfortunately, understanding electricity is a tall order. Don’t let this discourage or dissuade you: Even the smartest physicists in the world don’t really understand it.
At the start of this chapter, you examine the very nature of electricity: what it is and what causes it. This first part of the chapter will remind you of a seventh- or eighth-grade science class, as you delve into the insides of atoms and learn about protons, neutrons, and electrons.
The second part of this chapter introduces you to three things you have to know about electricity if you want to design and build circuits: current, voltage, and power — the Manny, Moe, and Jack of electricity. Or if you prefer, the Huey, Dewey, and Louie, or the bacon, lettuce, and tomato, or the — you get the idea.
Pondering the Wonder of Electricity
The exact nature of electricity is one of the core mysteries of the universe. Although we don’t really know exactly what electricity is, we do know a lot about what it does and how it behaves.
Strange as it may sound, your understanding of electricity will improve right away if you avoid using the term electricity to describe it. That’s because the term electricity isn’t very precise. We use the word electricity to refer to any of several different but related things. Each has a more precise name, such as electric charge, electric current, electric energy, electric field, and so on. All these things are commonly called electricity.
Electricity isn’t so much a specific thing, but a phenomenon that has many different faces. So to avoid confusion, I try to avoid the word electricity in the rest of this book. Instead, I use more precise terms such as charge or current.
I really hate to use the word phenomenon here because it sounds so scientific. I feel like I should wear a bow tie whenever I say the word phenomenon. I consulted my thesaurus to see if there was a simpler word I could use instead. None of the suggestions really seemed to fit, but the one that came closest was wonder.
WHERE DID THE WORD ELECTRICITY COME FROM?
Do you remember the movie Jurassic Park, where scientists discovered the DNA of dinosaurs locked inside bits of amber? Amber is fossilized tree resin, and it played a key role in the history of our knowledge about electricity.
Since the days of the ancient Greeks, people have known that if you rubbed sticks of amber with fur, the amber could then be used to raise the hair on your head and that lightweight objects like feathers would stick to it. They had no idea why this happened, but they knew that it did happen.
The Greek word for amber is elektron. The Latin version of the word was electricus.
At the beginning of the seventeenth century, an English scientist named William Gilbert began to study electricity. He used these ancient words to describe the phenomena he was investigating, including the Latin term electricus. The influence of Gilbert’s book, which was written in Latin, led to the word electricity in the English language.
Wonder isn’t a bad substitute. When it comes down to it, the phenomenon we call electricity is pretty amazing. It really does qualify as one of the great wonders of the universe.
Remember the so-called “Seven Wonders of the Ancient World,” which included the Great Pyramid of Giza, the Hanging Gardens of Babylon, the Temple of Artemis at Ephesus, the Statue of Zeus at Olympia, the Mausoleum of Halicarnassus, the Colossus of Rhodes, and the Lighthouse of Alexandria? If we were to make a list called “The Seven Wonders of the Universe,” I suppose it would have to include Matter, Gravity, Time, Light, Life, Pizza, and Electricity.
Looking for Electricity
One of the most amazing things about electricity is that it is, literally, everywhere. By that I don’t mean that electricity is commonplace or plentiful, or even that the universe has an abundant supply of electricity. Instead, what I mean is that electricity is a fundamental part of everything.
To get an idea of what I mean, consider a common misconception about electric current. Most of us think that wires carry electricity from place to place. When we plug in a vacuum cleaner and turn on the switch, we believe that electricity enters the vacuum cleaner’s power cord at the electrical outlet, travels through the wire to the vacuum cleaner, and then turns the motor to make the vacuum cleaner suck up dirt and grime and dog hair. But that’s not the case. The truth is that the electricity was already in the wire. The electricity is always in the wire, even when the vacuum cleaner is turned off or the power cord isn’t plugged in. That’s because electricity is a fundamental part of the copper atoms that make up the wire inside the power cord. Electricity is also a fundamental part of the atoms that make up the rubber insulation that protects you from being electrocuted when you touch the power cord. And it’s a fundamental part of the atoms that make up the tips of your finger which the rubber keeps from touching the wires.
In short, electricity is a fundamental part of the atoms that make up all matter. So, to understand what electricity is, we must first look at atoms.
Peering Inside Atoms
As you probably learned in grade school, all matter is made up of unbelievably tiny bits that are called atoms. They’re so tiny that the period at the end of this sentence contains several trillion of them.
It’s hard for us to comprehend numbers as large as trillions. For the sake of comparison, suppose you could enlarge the period at the end of this sentence until it was about the size of Texas. Then, each atom would be about the size of — you guessed it — the period at the end of this sentence.
The word atom comes from an ancient Greek fellow named Democritus. Contrary to what you might expect, the word atom doesn’t mean “really small.” Rather, it means “undividable.” Atoms are the smallest part of matter that can’t be divided without changing it to a different kind of matter. In other words, if you divide an atom of a particular element, the resulting pieces are no longer the same thing.
For example, suppose you have a handful of some basic element such as copper and you cut it in half. You now have two pieces of copper. Toss one of them aside, and cut the other one in half. Again, you have two pieces of copper. You can keep doing this, dividing your piece of copper into ever smaller halves. But eventually, you’ll get to the point where your piece of copper consists of just a single copper atom.
If you try to cut that single atom of copper in half, the resulting pieces will not be copper. Instead, you’ll have a collection of the basic particles that make up atoms. There are three such particles, called neutrons, protons, and electrons.
The neutrons and protons in each atom are clumped together in the middle of the atom, in what is called the nucleus. The electrons spin around the outside of the atom.
When I first learned about atoms as a kid, I was taught that the electrons orbit around the nucleus much like planets orbit around the sun in our solar system. Even today, kids are taught this. School children are still being taught to create models of atoms using Styrofoam balls and wires, like the one shown in Figure 2-1.
That turns out to be a really bad analogy. Instead, the electrons whiz around the nucleus in a cloud that’s called, appropriately enough, the electron cloud. Electron clouds have weird shapes and properties, and strangely enough, it’s next to impossible to figure