Dehornoy order explained

In the mathematical area of braid theory, the Dehornoy order is a left-invariant total order on the braid group, found by Patrick Dehornoy. Dehornoy's original discovery of the order on the braid group used huge cardinals, but there are now several more elementary constructions of it.

Definition

Suppose that

\sigma_1,\ldots,\sigma_n-1

are the usual generators of the braid group

B_n

strings. Define a

\sigma_i

-positive word to be a braid that admits at least one expression in the elements

\sigma_1,\ldots,\sigma_n-1

and their inverses, such that the word contains

\sigma_i

, but does not contain

	-1
\sigma
	i

nor

	\pm1
\sigma
	j

for

j<i

The set

of positive elements in the Dehornoy order is defined to be the elements that can be written as a

\sigma_i

-positive word for some

. We have:

PP\subseteqP;

P,\{1\}

and

P^-1

are disjoint ("acyclicity property");

the braid group is the union of

P,\{1\}

and

P^-1

("comparison property").

These properties imply that if we define

a<b

a^-1b\inP

then we get a left-invariant total order on the braid group. For example,

\sigma₁<\sigma₂\sigma₁

because the braid word

	-1
\sigma
	1

\sigma₂\sigma₁

is not

\sigma₁

-positive, but, by the braid relations, it is equivalent to the

\sigma₁

-positive word

\sigma_2\sigma₁

	-1
\sigma
	2

, which lies in

History

Set theory introduces the hypothetical existence of various "hyper-infinity" notions such as large cardinals. In 1989, it was proved that one such notion, axiom

I₃

, implies the existence of an algebraic structure called an acyclic shelf which in turn implies the decidability of the word problem for the left self-distributivity law

LD:x(yz)=(xy)(xz),

a property that is a priori unconnected with large cardinals.

l{G}_LD

that captures the geometrical aspects of the

law. As a result, an acyclic shelf was constructed on the braid group

B_infty

, which happens to be a quotient of

l{G}_LD

, and this implies the existence of the braid order directly. Since the braid order appears precisely when the large cardinal assumption is eliminated, the link between the braid order and the acyclic shelf was only evident via the original problem from set theory.

Properties

The existence of the order shows that every braid group

B_n

is an orderable group and that, consequently, the algebras

\ZB_n

and

\CB_n

have no zero-divisor.

n\geqslant3

, the Dehornoy order is not invariant on the right: we have

\sigma₂<\sigma₁

and

\sigma₂\sigma₁>

	2
\sigma
	1

. In fact no order of

B_n

with

n\geqslant3

may be invariant on both sides.

n\geqslant3

, the Dehornoy order is neither Archimedean, nor Conradian: there exist braids

\beta_1,\beta₂

satisfying

	p
\beta
	1

<\beta₂

for every

(for instance

\beta₁=\sigma₂

and

\beta₂=\sigma₁

), and braids

\beta_1,\beta₂

greater than

satisfying

\beta₁>\beta₂

	p
\beta
	1

for every

(for instance,

\beta₁=

	-1
\sigma
	2

\sigma₁

and

\beta₂=

	-2
\sigma
	2

\sigma₁

The Dehornoy order is a well-ordering when restricted to the positive braid monoid

	+
B
	n

generated by

\sigma_1,\ldots,\sigma_n-1

. The order type of the Dehornoy order restricted to

	+
B
	n

is the ordinal

	\omegaⁿ
\omega

The Dehornoy order is also a well-ordering when restricted to the dual positive braid monoid

	*+
B
	n

generated by the elements

\sigma_i...\sigma_j-1\sigma_j

	-1
\sigma
	j-1

...

	-1
\sigma
	i

with

1\leqslanti<j\leqslantn

, and the order type of the Dehornoy order restricted to

	*+
B
	n

is also

	\omegaⁿ
\omega

As a binary relation, the Dehornoy order is decidable. The best decision algorithm is based on Dynnikov's tropical formulas, see Chapter XII of; the resulting algorithm admits a uniform complexity

O(\ell²⁾

Connection with knot theory

\Delta_n

be Garside's fundamental half-turn braid. Every braid

\beta

lies in a unique interval

	2m
[\Delta
	n

	2m+2
\Delta
	n

)

; call the integer

the Dehornoy floor of

\beta

, denoted

\lfloor\beta\rfloor

. Then the link closure of braids with a large floor behave nicely, namely the properties of

\widehat{\beta}

can be read easily from

\beta

. Here are some examples.

\vert\lfloor\beta\rfloor\vert>1

then

\widehat{\beta}

is prime, non-split, and non-trivial.

\vert\lfloor\beta\rfloor\vert>1

and

\widehat{\beta}

is a knot, then

\widehat{\beta}

is a toric knot if and only if

\beta

is periodic,

\widehat{\beta}

is a satellite knot if and only if

\beta

is reducible, and

\widehat{\beta}

is hyperbolic if and only if

\beta

is pseudo-Anosov