In universal algebra
an *algebra* consists of some sets of elements
(think of each set as the set of values of a type)
and some operations, which map elements to elements.

For example, suppose you have a type of "list elements" and a
type of "lists". As operations you have the "empty list", which is a 0-argument
function returning a "list", and a "cons" function which takes two arguments,
a "list element" and a "list", and produce a "list".

At this point there are many algebras that fit the description,
as two undesirable things may happen:

There could be elements in the "list" set which cannot be built
from the "empty list" and the "cons operation", so-called "junk".
This could be lists starting from some element that fell from the sky,
or loops without a beginning, or infinite lists.

The results of "cons" applied to different arguments could be equal,
e.g. consing an element to a non-empty list
could be equal to the empty list. This is sometimes called "confusion".

An algebra which has neither of these undesirable properties is called
*initial*, and this is the intended meaning of the abstract data type.

The name initial derives from the property that there is exactly
one homomorphism from the initial algebra to any given algebra.
Essentially you can evaluate the value of a list by applying the operations
in the other algebra, and the result is well-defined.

It gets more complicated for polymorphic types ...