1. UNEQUAL COUPLING
TREE DIAGRAMS
SPLITTING DIAGRAMS
aka “TREE” DIAGRAMS

2. WHERE DOES THE N+1 RULE WORK ?
The n+1 rule works only for protons in aliphatic chains
and rings, and then under special conditions.
There are two requirements for the n+1 rule to work:
1) All 3J values must be the same all along the chain.
2) There must be free rotation or inversion (rings) to
make all of the hydrogens on a single carbon be
nearly equivalent.

3. C H 3Ja = 3Jb THE TYPICAL SITUATION WHERE THE n+1 RULE APPLIES
Hydrogens can
interchange their
positions by
rotations about
the C-C bonds. C H
3Ja = 3Jb
This makes all the
hydrogens on each
of the carbon atoms
equivalent.
All the couplings
along the chain
have the same J value.

4. WHAT HAPPENS WHEN THE J VALUES ARE NOT EQUAL ?
3Ja = 3Jb C C C H H H
3Ja Jb
In this situation each coupling must be considered
independently of the other.
A “splitting tree” is constructed

5. USE THESE VALUES C H
7 Hz Hz

6. CONSTRUCTING A TREE DIAGRAM
SPLITTING FROM
HYDROGENS TO THE LEFT H H H
-CH2-CH2-CH2-
LEVEL ONE C C C
The largest J value
is usually used first. H H H
Two neighbors gives
a triplet.
3Ja = 7
The next splittings will
be added to each leg of
the first splitting.
Each level of the
splitting uses the
n+1 rule.

7. CONSTRUCTING A TREE DIAGRAM
ADD SPLITTING FROM
HYDROGENS TO THE RIGHT H H H
-CH2-CH2-CH2- C C C C H H H H
3Ja = 7
3Jb = 3
FIRST LEVEL
SECOND LEVEL
LEVEL TWO
triplet of triplets
The smaller splitting
is used second.
EACH LEG OF LEVEL ONE IS SPLIT
It is also a triplet.

8. WHEN BOTH 3J VALUES ARE THE SAME
The n+1 rule is followed …..
LEVEL ONE
Splitting from
hydrogens on
the left
-CH2-CH2-CH2-
INTENSITIES
n+1 = (4 + 1) = 5
1:2:1
1:2:1
LEVEL TWO
1:2:1
Splitting from
hydrogens on
the right +
1:2:1
1:4:6:4:1
Splittings
overlap
….. because of overlapping legs.
You get the quintet predicted by
the n+1 rule.
WHEN THE n+1 RULE APPLIES WE CAN JUMP TO THE FINAL RESULT - NO TREE NEEDED

9. 2-PHENYLPROPANAL
A case where there are unequal J values.

10. Spectrum of 2-Phenylpropanalb d
J = 7 Hz c
TMS a c
J = 2 Hz d b

11. 3J1 = 7 Hz 3J2 = 2 Hz ANALYSIS OF METHINE HYDROGEN’S SPLITTING 7 Hz
Rather than the expected
quintet …..
the methine hydrogen
is split by two different
3J values.
quartet
by -CH3
3J1 = 7 Hz
3J2 = 2 Hz
doublet
by -CHO
ANALYSIS
OF METHINE
HYDROGEN’S
SPLITTING
quartet of doublets

12. PURE ETHANOL

13. ETHANOL HO-CH2-CH3 400 MHz Old sample Rapid exchange catalyzed
by impurities
hydrogen on OH
is decoupled
HO-CH2-CH3
triplet
broad
singlet
quartet

14. ETHANOL 400 MHz expansion expansion doublet of triplet quartets
Ultrapure sample (new)
Slow or no exchange
400 MHz
triplet

15. J = 7
J = 5
J = 7
J = 5
triplet
quartet of doublets
triplet

16. VINYL ACETATE
ALKENE HYDROGENS

17. PROTONS ON C=C DOUBLE BONDS
COUPLING CONSTANTS
PROTONS ON C=C DOUBLE BONDS
3J-cis = 8-10 Hz
3J-trans = Hz
protons on the same carbon
2J-geminal = 0-2 Hz
For protons on saturated aliphatic chains 3J ~ 8 Hz

18. NMR Spectrum of Vinyl Acetate
60 MHz

19. Analysis of Vinyl AcetateH 3 O HC HA HB
3J-trans > 3J-cis > 2J-gem HC HB HA
3JAC
3JBC
3JBC
cis
trans
trans
3JAC
2JAB
2JAB
cis
gem
gem

20. 2,4-DINITROANISOLE
BENZENE HYDROGENS

21. 2,4-DINITROANISOLE
400 MHz

22. 2,4-DINITROANISOLE
8.72 ppm ppm ppm

23. END