Flip (mathematics) explained

Flip (mathematics) should not be confused with Flip (geometry).

In algebraic geometry, flips and flops are codimension-2 surgery operations arising in the minimal model program, given by blowing up along a relative canonical ring. In dimension 3 flips are used to construct minimal models, and any two birationally equivalent minimal models are connected by a sequence of flops. It is conjectured that the same is true in higher dimensions.

The minimal model program

See main article: Minimal model program. The minimal model program can be summarised very briefly as follows: given a variety

, we construct a sequence of contractions

X=X_{1 →}X₂ → … → X_n

, each of which contracts some curves on which the canonical divisor

K
	X_i

is negative. Eventually,

K
	X_n

should become nef (at least in the case of nonnegative Kodaira dimension), which is the desired result. The major technical problem is that, at some stage, the variety

X_i

may become 'too singular', in the sense that the canonical divisor

K
	X_i

is no longer a Cartier divisor, so the intersection number

K
	X_i

⋅ C

with a curve

is not even defined.

The (conjectural) solution to this problem is the flip. Given a problematic

X_i

as above, the flip of

X_i

is a birational map (in fact an isomorphism in codimension 1)

f\colonX_i →

	+
X
	i

to a variety whose singularities are 'better' than those of

X_i

. So we can put

X_i+1=

	+
X
	i

, and continue the process.^[1]

Two major problems concerning flips are to show that they exist and to show that one cannot have an infinite sequence of flips. If both of these problems can be solved, then the minimal model program can be carried out. The existence of flips for 3-folds was proved by . The existence of log flips, a more general kind of flip, in dimension three and four were proved by whose work was fundamental to the solution of the existence of log flips and other problems in higher dimension. The existence of log flips in higher dimensions has been settled by . On the other hand, the problem of termination—proving that there can be no infinite sequence of flips—is still open in dimensions greater than 3.

Definition

f\colonX\toY

is a morphism, and K is the canonical bundle of X, then the relative canonical ring of f is

oplus_mf_*(l{O}_X(mK))

and is a sheaf of graded algebras over the sheaf

l{O}_Y

of regular functions on Y.The blowup

f^+\colonX⁺⁼\operatorname{Proj}(oplus_mf_*(l{O}_X(mK)))\toY

of Y along the relative canonical ring is a morphism to Y. If the relative canonical ring is finitely generated (as an algebra over

l{O}_Y

) then the morphism

f⁺

is called the flip of

-K

is relatively ample, and the flop of

if K is relatively trivial. (Sometimes the induced birational morphism from

X⁺

is called a flip or flop.)

In applications,

is often a small contraction of an extremal ray, which implies several extra properties:

The exceptional sets of both maps

and

f⁺

have codimension at least 2,

and

X⁺

only have mild singularities, such as terminal singularities.

and

f⁺

are birational morphisms onto Y, which is normal and projective.

All curves in the fibers of

and

f⁺

are numerically proportional.

Examples

The first example of a flop, known as the Atiyah flop, was found in .Let Y be the zeros of

xy=zw

A⁴

, and let V be the blowup of Y at the origin. The exceptional locus of this blowup is isomorphic to

P^{1 x}P¹

, and can be blown down to

P¹

in two different ways, giving varieties

X₁

and

X₂

. The natural birational map from

X₁

X₂

is the Atiyah flop.

introduced Reid's pagoda, a generalization of Atiyah's flop replacing Y by the zeros of

xy=(z+w^k)(z-w^k)

Notes and References

More precisely, there is a conjecture stating that every sequence
X₀

⇢
X₁

⇢
...

⇢
X_n

⇢
…

of flips of varieties with Kawamata log terminal singularities, projective over a fixed normal variety
Z

terminates after finitely many steps.