It's really not that complicated.
It's really not that complicated.
The number of peaks always corresponds to the the number of hydrogens that are not equivalent. What do I mean by that? Look at the following example:
-The hydrogens on the two red methyl groups are magnetically equivalent (Start from the 1st methyl group and go counter clockwise. You'll see, H, CH3, H, CH3, Cl. Start from the 2nd methyl group and go counter-clockwise. You'll see the same exact substituents). So, they both represent one peak.
-The two green hydrogens are also magnetically equivalent. So, they both represent one peak.
-The hydrogens on the blue methyl group are magnetically different from those of the green methyl groups and the two green hydrogens (Look at the neighboring groups moving in clockwise and counter clockwise fashion, and you'll see that these neighboring groups are not like the neighboring groups of the blue and green hydrogens). So, these protons represent our 3rd peak.
So far, we have determined that we have 3 peaks. Now let's look at the splitting pattern:
Protons that are a maximum of 3 bonds away from one another can split each other in n+1 fashion (n = # of protons). What does this mean?
-Look at the red hydrogens. The green hydrogen is 2 bonds away, so it can split the peak representing the red hydrogens. How does it split it?
There is only 1 green hydrogen next to each of these methyl groups. So:
n + 1 = 1+1 = 2 (The peak representing the the red hydrogens will be a doublet).
-Look at the green hydrogen. The green hydrogen has 6 neighboring protons (3 belong to the red methyl group and 3 belong to the blue methyl group). So the splitting pattern is 6 + 1 = 7
-Look at the blue hydrogens. There are 2 neighboring hydrogens (The green ones). So the splitting pattern is 2 + 1 = 3
In conclusion, you'll have 3 peaks:
-One doublet
-One triplet
-And one with 7 splits
Here are couple of more examples:
Hope this helps!
For the cyclohexane...
I agree we will have 6 peaks...but wouldn't the proton attached to the ring where Cl is be a triplet (because of the 2 protons attached to the ring on either side of it)? I agree about the doublet for the protons in the red methyl groups...and would the protons attached to the ring at the red methyls be split into 7 (3 H on the methyl, 2 H attached to the ring below it, and 1 H attached to the ring at the Cl)? The green CH2 groups would be a triplet (H attached to the ring at the blue methyl plus H attached to the ring at red methyl)....and the then protons that are in the blue methyl group would just be a doublet, right?
Someone correct me if I severely messed that up!
