List of complex and algebraic surfaces

Kodaira dimension −∞

[Rational surface]s

• Projective plane

[Quadric surface]s

• Cone (geometry)
• Cylinder
• Ellipsoid
• Hyperboloid
• Paraboloid
• Sphere
• Spheroid

Rational [cubic surface]s

• Cayley's nodal [cubic surface |Cayley nodal cubic surface], a certain cubic surface with 4 nodes
• Cayley's ruled cubic surface
• Clebsch surface or Klein icosahedral surface
• Fermat cubic
• Monkey saddle
• Parabolic conoid
• Plücker's conoid
• Whitney umbrella

Rational [quartic surface]s

• Châtelet surfaces
• Dupin cyclides, inversions of a cylinder, torus, or double cone in a sphere
• Gabriel's horn
• Right circular conoid
• Roman surface or Steiner surface, a realization of the real projective plane in real affine space
• Tori, surfaces of revolution generated by a circle about a coplanar axis

Other rational surfaces in space

• Boy's surface, a sextic realization of the real projective plane in real affine space
• Enneper surface, a nonic minimal surface
• Henneberg surface, a minimal surface of degree 15
• Bour's minimal surface, a surface of degree 16
• Richmond surfaces, a family of minimal surfaces of variable degree

Other families of rational surfaces

• Coble surfaces
• Del Pezzo surfaces, surfaces with an ample anticanonical divisor
• Hirzebruch surfaces, rational ruled surfaces
• Segre surfaces, intersections of two quadrics in projective 4-space
• Unirational surfaces of characteristic 0
• Veronese surface, the Veronese embedding of the projective plane into projective 5-space
• White surfaces, the blow-up of the projective plane at points by the linear system of degree- curves through those points
• * Bordiga surfaces, the White surfaces determined by families of quartic curves

[Class VII surface]s

• Vanishing second Betti number:
• * Hopf surfaces
• * Inoue surfaces; several other families discovered by Inoue have also been called "Inoue surfaces"
• Positive second Betti number:
• * Enoki surfaces
• * Inoue–Hirzebruch surfaces
• * Kato surfaces

Kodaira dimension 0

[K3 surface]s

• Kummer surfaces
• * Tetrahedroids, special Kummer surfaces
• * Wave surface, a special tetrahedroid
• Plücker surfaces, birational to Kummer surfaces
• Weddle surfaces, birational to Kummer surfaces
• Smooth quartic surfaces
• Supersingular K3 surfaces

[Enriques surface]s

• Reye congruences, the locus of lines that lie on at least two quadrics in a general three dimensional linear system of quadric surfaces in projective 3-space.
• The quotient of a K3 surface under a fixpointfree involution.

[Abelian surface]s

Other classes of dimension-0 surfaces

• Non-classical Enriques surfaces, a variation on the notion of Enriques surfaces that only exist in characteristic two
• Hyperelliptic surfaces or bielliptic surfaces; quasi-hyperelliptic surfaces are a variation of this notion that exist only in characteristics two and three
• Kodaira surfaces

Kodaira dimension 1

• Dolgachev surfaces

Kodaira dimension 2 (surfaces of general type">surface of general type">surfaces of general type)

• Barlow surfaces
• Beauville surfaces
• Burniat surfaces
• Campedelli surfaces; surfaces of general type with the same Hodge numbers as Campedelli surfaces are called numerical Campidelli surfaces
• Castelnuovo surfaces
• Catanese surfaces
• Fake projective planes or Mumford surfaces, surfaces with the same Betti numbers as projective plane but not isomorphic to it
• Fano surface of lines on a non-singular 3-fold; sometimes, this term is taken to mean del Pezzo surface
• Godeaux surfaces; surfaces of general type with the same Hodge numbers as Godeaux surfaces are called numerical Godeaux surfaces
• Horikawa surfaces
• Todorov surfaces

Families of surfaces with members in multiple classes

• Surfaces that are also Shimura varieties:
• * Hilbert modular surfaces
• * Humbert surfaces
• * Picard modular surfaces
• * Shioda modular surfaces
• Elliptic surfaces, surfaces with an elliptic fibration; quasielliptic surfaces constitute a modification this idea that occurs in finite characteristic
• * Raynaud surfaces and generalized Raynaud surfaces, certain quasielliptic counterexamples to the conclusions of the Kodaira vanishing theorem
• Exceptional surfaces, surfaces whose Picard number achieve the bound set by the central Hodge number h^1,1
• Kähler surfaces, complex surfaces with a Kähler metric; equivalently, surfaces for which the first Betti number b₁ is even
• Minimal surfaces, surfaces that can't be obtained from another by blowing up at a point; they have no connection with the minimal surfaces of differential geometry
• Nodal surfaces, surfaces whose only singularities are nodes
• * Cayley's nodal cubic, which has 4 nodes
• * Kummer surfaces, quartic surfaces with 16 nodes
• * Togliatti surface, a certain quintic with 31 nodes
• * Barth surfaces, referring to a certain sextic with 65 nodes and decic with 345 nodes
• * Labs surface, a certain septic with 99 nodes
• * Endrass surface, a certain surface of degree 8 with 168 nodes
• * Sarti surface, a certain surface of degree 12 with 600 nodes
• Quotient surfaces, surfaces that are constructed as the orbit space of some other surface by the action of a finite group; examples include Kummer, Godeaux, Hopf, and Inoue surfaces
• Zariski surfaces, surfaces in finite characteristic that admit a purely inseparable dominant rational map from the projective plane