Twisted cubic explained

In mathematics, a twisted cubic is a smooth, rational curve C of degree three in projective 3-space P3. It is a fundamental example of a skew curve. It is essentially unique, up to projective transformation (the twisted cubic, therefore). In algebraic geometry, the twisted cubic is a simple example of a projective variety that is not linear or a hypersurface, in fact not a complete intersection. It is the three-dimensional case of the rational normal curve, and is the image of a Veronese map of degree three on the projective line.

Definition

The twisted cubic is most easily given parametrically as the image of the map

\nu:P1\toP3

[S:T]

the value

\nu:[S:T]\mapsto[S3:S2T:ST2:T3].

In one coordinate patch of projective space, the map is simply the moment curve

\nu:x\mapsto(x,x2,x3)

(x,x2,x3)

.

The twisted cubic is a projective variety, defined as the intersection of three quadrics. In homogeneous coordinates

[X:Y:Z:W]

on P3, the twisted cubic is the closed subscheme defined by the vanishing of the three homogeneous polynomials

F0=XZ-Y2

F1=YW-Z2

F2=XW-YZ.

It may be checked that these three quadratic forms vanish identically when using the explicit parameterization above; that is, substitute x3 for X, and so on.

More strongly, the homogeneous ideal of the twisted cubic C is generated by these three homogeneous polynomials of degree 2.

Properties

The twisted cubic has the following properties:

XZ-Y2

and

Z(YW-Z2)-W(XW-YZ)

, but not a scheme-theoretic or ideal-theoretic complete intersection; meaning to say that the ideal of the variety cannot be generated by only 2 polynomials; a minimum of 3 are needed. (An attempt to use only two polynomials make the resulting ideal not radical, since

(YW-Z2)2

is in it, but

YW-Z2

is not).

References