Eisenstein integer

"Eulerian integer" and "Euler integer" redirect here. For other uses, see List of topics named after Leonhard Euler § Euler's numbers.

Eisenstein integers as intersection points of a triangular lattice in the complex plane

In mathematics, Eisenstein integers (named after Gotthold Eisenstein), also known^[1] as Eulerian integers (after Leonhard Euler), are complex numbers of the form

z = a + b\omega ,

where a and b are integers and

\omega = \frac{1}{2}(-1 + i\sqrt 3) = e^{2\pi i/3}

is a primitive (non-real) cube root of unity. The Eisenstein integers form a triangular lattice in the complex plane, in contrast with the Gaussian integers, which form a square lattice in the complex plane.

Properties

The Eisenstein integers form a commutative ring of algebraic integers in the algebraic number field Q(ω) — the third cyclotomic field. To see that the Eisenstein integers are algebraic integers note that each z = a + bω is a root of the monic polynomial

z^2 - (2a - b)z + (a^2 - ab + b^2). \,\!

In particular, ω satisfies the equation

\omega^2 + \omega + 1 = 0. \,\!

The product of two Eisenstein integers $a+b\omega$ and $c+d\omega$ is given explicitly by

(a+b\omega) \cdot (c+d\omega)=(ac-bd)+(bc+ad-bd)\omega. \,\!

The norm of an Eisenstein integer is just the square of its modulus and is given by

|a+b\omega|^2 = a^2 - ab + b^2. \,\!

Thus the norm of an Eisenstein integer is always an ordinary (rational) integer. Since

4a^2-4ab+4b^2=(2a-b)^2+3b^2, \,\!

the norm of a nonzero Eisenstein integer is positive.

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, ±ω²}

These are just the Eisenstein integers of norm one.

Eisenstein primes

Main article: Eisenstein prime

Small 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 = zx.

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 non-unit divisors are of the form ux where u is any of the six units.

It may be shown that 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 therefore be 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.

Every Eisenstein integer a + bω whose norm a² − ab + b² is a rational prime is an Eisenstein prime. In fact, every Eisenstein prime is of this form, or is a product of a unit and a rational prime congruent to 2 mod 3.

Euclidean domain

The ring of Eisenstein integers forms a Euclidean domain whose norm N is given by

N(a + b\,\omega) = a^2 - a b + b^2. \,\!

This can be derived as follows:

\begin{align}N(a+b\,\omega) &=|a+b\,\omega|^2\\ &=(a+b\,\omega)(a+b\,\bar\omega)\\ &=a^2 + ab(\omega+\bar\omega) + b^2\\ &=a^2 - ab + b^2.\end{align}

Quotient of C by the Eisenstein integers

The quotient of the complex plane C by the lattice containing all Eisenstein integers is a complex torus of real dimension 2. This is one of two tori with maximal symmetry among all such complex tori. This torus can be obtained by identifying each of the three pairs of opposite edges of a regular hexagon. (The other maximally symmetric torus is the quotient of the complex plane by the additive lattice of Gaussian integers, and can be obtained by identifying each of the two pairs of opposite sides of a square fundamental domain, such as [0,1]×[0,1].)

Notes

↑ Surányi, László (1997). Algebra. TYPOTEX. p. 73. and Szalay, Mihály (1991). Számelmélet. Tankönyvkiadó. p. 75. both call these numbers “Euler-egészek”, that is, Eulerian integers. The latter claims Euler worked with them in a proof.

External links

Eisenstein Integer--from MathWorld

Algebraic numbers

Algebraic integer Chebyshev nodes Constructible number Conway's constant ³√2 Eisenstein integer Gaussian integer $φ$ Kummer ring Perron number Pisot–Vijayaraghavan number Quadratic irrational number ℚ Root of unity Salem number $δ$ _$S$ √2 √3 √5 ¹²√2		ℚ

Systolic geometry

1-systoles of surfaces	Loewner's torus inequality Pu's inequality Filling area conjecture Bolza surface Systoles of surfaces Eisenstein integers

1-systoles of manifolds	Gromov's systolic inequality for essential manifolds Essential manifold Filling radius Hermite constant

Higher systoles	Gromov's inequality for complex projective space Systolic freedom Systolic category

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