In this video, we're going to become experts on counting pi electrons. Technically, a pi electron is any electron found within an unhybridized p orbital. Technical definition. However, for the purposes of this video, I think it's just easier if we memorize a few different types of electrons that are pi electrons and that's going to kind of cover our bases. So we can learn that double bonds, radicals, and cations all contribute different amounts of electrons to pi electrons. Radicals contribute 1 pi electron and radicals contribute 1 pi electron. Cations, because of the fact that they have empty orbitals, you got it, they contribute 0 electrons. So, simply the job of counting up pi electrons is as easy as counting with your fingers how many electrons you see by counting up with this method. So I'm going to have you guys do 6 compounds and figure out the pi electrons for those six. Go ahead and start off with the first one here and use the rule that I gave you to count up all the pi electrons you see, and then we'll go ahead and do the answer.
Pi Electrons - Online Tutor, Practice Problems & Exam Prep
Counting pi electrons
Video transcript
Count the pi electrons present
Video transcript
The answer for the 1st molecule is 6 because I've got 2 from this double bond. I've got 2 from this double bond. I've also got another 2 from this double bond and I've got 0 from this cation. You add it all together and you get 6 pi electrons. Easy. Move on to the next one.
Count the pi electrons present
Video transcript
The answer for this next one was 10 pi electrons because I've got 2, 2, 2, 2, 2. That equals 10 pi electrons. Too easy. Let's move on to the next one.
Count the pi electrons present
Video transcript
The answer for this next compound was 4 pi electrons because I had 2 electrons coming from my double bond and then I had another 2 coming from my anion, which we said contributed 2 pi electrons as well. That would give us 4 pi electrons total. Now, in order to answer the next three questions, we're going to have to get a handle on this tricky notation. If you see a hydrocarbon ring with just a charge in the middle, that means you've got a lazy organic chemist on your hands. But hey, this is an acceptable notation and you do need to learn what it means. Basically, if you just see a charge in the middle, that means that we're going to assume, so I'm just going to put here by definition, this means that we're going to assume alternating double bonds and then the space left over, or the carbon left over, the atom left over would possess that charge. That means that this molecule, that 5 of a ring is actually a shortcut or a shorthand for a 5 carbon diene with a positive charge on 1 carbon. That being said, go ahead and try to figure out how many pi electrons that has, and then use that information to then draw the correct structures of the following tubes so that you can get the right answers for those as well. You got this.
Count the pi electrons present
Video transcript
The correct answer for this one was 4 now that we know how to draw it because you had 2, 2 and 0 giving us a total of 4 pi electrons. Go ahead and try the next one.
Count the pi electrons present
Video transcript
The correct structure of this molecule was a triangle with simply one double bond and a negative charge in the space afterwards because there was only enough space for one double bond total. This means that this molecule would have a total of 4 pi electrons. Let's move on to the last question.
Count the pi electrons present
Video transcript
The answer for this last one was 8 pi electrons. How do we get the answer? Because the negative charge in the middle meant that we had to assume double bond, double bond, double bond with a negative charge here. I can just cross that out. We would get 8 pi electrons from the 3 double bonds and the anion which could contribute electrons 7 and 8. So this would be 8 pi electrons total. Now I know that you're not really completely sure how important this pi electron thing is. But it's a huge deal when we're talking about aromaticity. Now that you know how to count them, let's go ahead and figure out why they're going to be so important for aromaticity.