Moufang loop

In mathematics, a Moufang loop is a special kind of algebraic structure. It is similar to a group in many ways but need not be associative. Moufang loops were introduced by Ruth Moufang (1935).

Definition

A Moufang loop is a loop Q that satisfies any one of the following equivalent identities for all x, y, z in Q (the binary operation in Q is denoted by juxtaposition):

  1. z(x(zy)) = ((zx)z)y;
  2. x(z(yz)) = ((xz)y)z
  3. (zx)(yz) = (z(xy))z
  4. (zx)(yz) = z((xy)z).

These identities are known as Moufang identities.

Examples

It follows that u^2 = 1 and ug = g^{-1}u. With the above product M(G,2) is a Moufang loop. It is associative if and only if G is abelian.
where |A| is the number of elements of the code word A, and so on. For more details see Conway, J. H.; Curtis, R. T.; Norton, S. P.; Parker, R. A.; and Wilson, R. A.: Atlas of Finite Groups: Maximal Subgroups and Ordinary Characters for Simple Groups. Oxford, England.

Properties

Associativity

Moufang loops differ from groups in that they need not be associative. A Moufang loop that is associative is a group. The Moufang identities may be viewed as weaker forms of associativity.

By setting various elements to the identity, the Moufang identities imply

Moufang's theorem states that when three elements x, y, and z in a Moufang loop obey the associative law: (xy)z = x(yz) then they generate an associative subloop; that is, a group. A corollary of this is that all Moufang loops are di-associative (i.e. the subloop generated by any two elements of a Moufang loop is associative and therefore a group). In particular, Moufang loops are power associative, so that exponents xn are well-defined. When working with Moufang loops, it is common to drop the parenthesis in expressions with only two distinct elements. For example, the Moufang identities may be written unambiguously as

  1. z(x(zy)) = (zxz)y
  2. ((xz)y)z = x(zyz)
  3. (zx)(yz) = z(xy)z.

Left and right multiplication

The Moufang identities can be written in terms of the left and right multiplication operators on Q. The first two identities state that

while the third identity says

for all x,y,z in Q. Here B_z = L_zR_z = R_zL_z is bimultiplication by z. The third Moufang identity is therefore equivalent to the statement that the triple (L_z, R_z, B_z) is an autotopy of Q for all z in Q.

Inverse properties

All Moufang loops have the inverse property, which means that each element x has a two-sided inverse x−1 which satisfies the identities:

x^{-1}(xy) = y = (yx)x^{-1}

for all x and y. It follows that (xy)^{-1} = y^{-1}x^{-1} and x(yz) = e if and only if (xy)z = e.

Moufang loops are universal among inverse property loops; that is, a loop Q is a Moufang loop if and only if every loop isotope of Q has the inverse property. If follows that every loop isotope of a Moufang loop is a Moufang loop.

One can use inverses to rewrite the left and right Moufang identities in a more useful form:

Lagrange property

A finite loop Q is said to have the Lagrange property if the order of every subloop of Q divides the order of Q. Lagrange's theorem in group theory states that every finite group has the Lagrange property. It was an open question for many years whether or not finite Moufang loops had Lagrange property. The question was finally resolved by Alexander Grishkov and Andrei Zavarnitsine, and independently by Stephen Gagola III and Jonathan Hall, in 2003: Every finite Moufang loop does have the Lagrange property. More results for the theory of finite groups have been generalized to Moufang loops by Stephen Gagola III in recent years.

Moufang quasigroups

Any quasigroup satisfying one of the Moufang identities must, in fact, have an identity element and therefore be a Moufang loop. We give a proof here for the third identity:

Let a be any element of Q, and let e be the unique element such that ae = a. Then for any x in Q, (xa)x = (x(ae))x = (xa)(ex). Cancelling gives x = ex so that e is a left identity element. Now let f be the element such that fe = e. Then (yf)e = (e(yf))e = (ey)(fe) = (ey)e = ye. Cancelling gives yf = y, so f is a right identity element. Lastly, e = ef = f, so e is a two-sided identity element.

The proofs for the first two identities are somewhat more difficult (Kunen 1996).

Open problems

Phillips' problem is an open problem in the theory presented by J. D. Phillips at Loops '03 in Prague. It asks whether there exists a finite Moufang loop of odd order with a trivial nucleus.

Recall that the nucleus of a loop (or more generally a quasigroup) is the set of x such that x(yz)=(xy)z, y(xz)=(yx)z and y(zx)=(yz)x hold for all y,z in the loop.

See also: Problems in loop theory and quasigroup theory

See also

References

External links

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