Eisenstein integer
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In mathematics, Eisenstein integers, named after Ferdinand Eisenstein, are complex numbers of the form
- z = a + bω
where and a and b are integers and
is a complex cube root of unity. The Eisenstein integers form a triangular lattice in the complex plane. Contrast with the Gaussian integers which form a square lattice in the complex plane.
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[edit] Properties
The Eisenstein integers form a commutative ring of algebraic integers in the algebraic number field Q(√−3). They also form a Euclidean domain.
To see that the Eisenstein integers are algebraic integers note that each z = a + bω is a root of the monic polynomial
- z2 − (2a − b)z + (a2 − ab + b2).
In particular, ω satisfies the equation
- ω2 + ω + 1 = 0.
The group of units in the ring of Eisenstein integers is the cyclic group formed by the sixth roots of unity in the complex plane. Specifically, they are
- {±1, ±ω or ±ω2}
These are just the Eisenstein integers with absolute value equal to one.
[edit] Eisenstein primes
If x and y are Eisenstein integers, we say that x divides y if there is some Eisenstein integer z such that
- y = z x.
This extends the notion of divisibility for ordinary integers. Therefore we may also extend the notion of primality; a non-unit Eisenstein integer x is said to be an Eisenstein prime if its only divisors are of the form ux and u where u is any of the six units.
It may be shown that the an ordinary prime number (or rational prime) which is 3 or congruent to 1 mod 3 is of the form x2 − xy + y2 for some integers x,y and may be therefore factored into (x + ωy)(x + ω2y) and because of that it is not prime in the Eisenstein integers. Ordinary primes congruent to 2 mod 3 cannot be factored in this way and they are primes in the Eisenstein integers as well. Also, a number of the form x2 − xy + y2 is rational prime iff x + ωy is an Eisenstein prime.
[edit] Euclidean domain
The ring of Eisenstein integers forms a Euclidean domain whose norm v is
- v(a + ωb) = a2 − ab + b2.
This can be derived by embedding the Eisenstein integers in the complex numbers: since
- v(a + ib) = a2 + b2
and since
it follows that
-
-
- .
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