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k3

K3, often written K3, refers to a class of compact complex surfaces in algebraic geometry that are distinguished by their rich geometric structure and simplicity of their canonical bundle. A K3 surface is a smooth, simply connected complex surface with trivial canonical bundle, equivalently a surface with vanishing first Chern class and a nowhere vanishing holomorphic two-form.

Topologically and Hodge-theoretically, a K3 surface has Betti numbers b0 = 1, b1 = 0, b2 = 22, b3

Explicit constructions include smooth quartic surfaces in projective 3-space, which are K3 by adjunction, and complete

K3 surfaces form a 20-dimensional moduli space of complex structures, and they obey a version of the

The name K3 was coined by André Weil in honor of Kummer, Kähler, and Kodaira. K3 surfaces

=
0,
b4
=
1,
and
Hodge
numbers
(h^{p,q})
with
h^{2,0}
=
h^{0,2}
=
1
and
h^{1,1}
=
20.
The
second
cohomology
H^2(S,
Z)
carries
a
natural
even,
unimodular
lattice
structure
of
signature
(3,19),
isomorphic
to
II_{3,19}
and
often
described
as
3H
⊕
2(-E8).
The
Picard
group,
or
Neron-Severi
group,
has
rank
ρ
between
0
and
20;
generic
K3
surfaces
have
ρ
=
0,
while
algebraic
K3
surfaces
satisfy
ρ
≥
1.
intersections
in
projective
spaces.
Kummer
surfaces,
obtained
by
resolving
the
singularities
of
the
quotient
of
an
abelian
surface
by
the
involution,
also
yield
K3
surfaces.
Torelli
theorem:
the
isomorphism
class
is
controlled
by
the
Hodge
structure
on
H^2
together
with
the
lattice
data.
In
differential
geometry,
K3
surfaces
are
examples
of
compact
hyperkähler
manifolds
with
holonomy
SU(2).
are
central
in
algebraic
geometry
and
mathematical
physics
due
to
their
rich
geometry,
moduli,
and
symmetry
properties.