E- and Z-alkenes

Basic IUPAC Organic Nomenclature

E- and Z-nomenclature of alkenes

On the previous pages, we looked at naming alkenes as cis- and trans-.

Misconception Alert!

cis ¹ Z and trans ¹ E

In general terms there is NO specific relationship between cis and trans / E and Z as they are based on fundamentally different naming rules.

It is important to note that the two methods are different (i.e. they are based on different rules) and they are NOT interchangeable, see below for an example.
The cis- / trans- style is based on the longest chain whereas the E/Z style is based on a set of priority rules.
You need to know both styles.


cis-but-2-ene or (Z)-but-2-ene	cis-2-chlorobut-2-ene or (E)-2-chlorobut-2-ene

The E- and Z- style is more reliable and particularly suited to tri- or tetra-substituted alkenes, and especially when the substituents are not alkyl groups.

The Cahn-Ingold-Prelog priority rules are used for naming geometric isomers (e.g. E- or Z-alkenes) and other stereoisomers (see later).

In order to apply the Cahn-Ingold-Prelog priority rules to alkenes:

Imagine splitting each alkene into two pieces, each piece containing one of the sp² C atoms from the C=C (i.e. the ends of the alkene)
Assign the priority based on the Cahn-Ingold-Prelog priority rules (high = 1, low = 2) to each atom attached to each sp² C based on atomic number

Subrules:
- Isotopes: H vs D ? Since isotopes have identical atomic numbers, the mass number is used to discriminate them so D > H
- Same atom attached ? By moving out away from the C=C one atom at a time, locate the first point of difference and apply the priority rule there.
Determine the relative position of the two higher priority groups
- If they are on the same side then it is a (Z)-alkene (German; zusammen = together)
- If they are on opposite sides then it is an (E)-alkene (German; entgegen = opposite)
If there is more than one C=C that can be E/Z, then the locant and the stereochemistry of each alkene needs to be included e.g. (2E,4Z)-

Example: but-2-ene


Step 1: Split the alkene into two pieces	Step 2: List the attached atoms looking for the first point of difference. Here we have C and H atoms attached.	Step 3: Assign the relative priorities. Since the atomic numbers C > H then the -CH₃ group is higher priority than H.	Step 4: Look at the relative positions of the higher priority groups: same side = Z, hence (Z)-but-2-ene


Step 1: Split the alkene into two pieces	Step 2: List the attached atoms looking for the first point of difference. Here we have C and H atoms attached.	Step 3: Assign the relative priorities. Since the atomic numbers C > H then the -CH₃ group is higher priority than H.	Step 4: Look at the relative positions of the higher priority groups: opposite side = E, hence (E)-but-2-ene

Example: 3-methylpent-2-ene


Step 1: Split the alkene into two pieces	Step 2: Assign the relative priorities. The two atoms attached to the left end C are C and H, so since the atomic numbers C > H then the -CH₃ group is higher priority.	Step 3: The two atoms attached to the right end C are both C. So we need to look at the atoms these C are attached to. List them out...we have C (H,H,H) and C (C,H,H) systems. This means that at the first point of difference (see the arrow), a C > H meaning that the ethyl group is higher priority.	Step 4: Look at the relative positions of the higher priority groups : opposite side = E, hence (E)-3-methylpent-2-ene.