F-theory

String theory

Fundamental objects
String Brane D-brane
Perturbative theory
Bosonic Superstring Type I Type II (IIA / IIB) Heterotic (SO(32) · E₈×E₈)
Non-perturbative results
S-duality T-duality M-theory AdS/CFT correspondence
Phenomenology
Phenomenology Cosmology Landscape
Mathematics
Mirror symmetry Monstrous moonshine
Related concepts Conformal field theory Holographic principle Kaluza–Klein theory Quantum gravity Supergravity Supersymmetry Theory of everything Twistor string theory
Theorists Arkani-Hamed Banks Dijkgraaf Duff Fischler Gates Gliozzi Green Greene Gross Gubser Harvey Hořava Kaku Klebanov Kontsevich Maldacena Mandelstam Martinec Minwalla Moore Motl Nekrasov Neveu Olive Polchinski Polyakov Randall Ramond Rohm Scherk Schwarz Seiberg Sen Shenker Sơn Strominger Sundrum Susskind 't Hooft Townsend Vafa Veneziano E. Verlinde H. Verlinde Witten Yau Zaslow
History Glossary

F-theory is a branch of string theory developed by Cumrun Vafa.^[1] The new vacua described by F-theory were discovered by Vafa and allowed string theorists to construct new realistic vacua — in the form of F-theory compactified on elliptically fibered Calabi–Yau four-folds. The letter "F" supposedly stands for "Father".^[2]

Compactifications

F-theory is formally a 12-dimensional theory, but the only way to obtain an acceptable background is to compactify this theory on a two-torus. By doing so, one obtains type IIB superstring theory in 10 dimensions. The SL(2,Z) S-duality symmetry of the resulting type IIB string theory is manifest because it arises as the group of large diffeomorphisms of the two-dimensional torus.

More generally, one can compactify F-theory on an elliptically fibered manifold (elliptic fibration), i.e. a fiber bundle whose fiber is a two-dimensional torus (also called an elliptic curve). For example, a subclass of the K3 manifolds is elliptically fibered, and F-theory on a K3 manifold is dual to heterotic string theory on a two-torus. Also, the modules of those theories should be isomorphic.

The well-known large number of semirealistic solutions to string theory referred to as the string theory landscape, with $10^{{500}}$ elements or so, is dominated by F-theory compactifications on Calabi–Yau four-folds.

Phenomenology

New models of Grand Unified Theory have recently been developed using F-theory.^[3]

Extra time dimensions

F-theory, as it has metric signature (11,1), as needed for the Euclidean interpretation of the compactification spaces (e.g. the four-folds), is not a "two-time" theory of physics.

However, the signature of the two additional dimensions is somewhat ambiguous due to their infinitesimal character. For example, the supersymmetry of F-theory on a flat background corresponds to type IIB (i.e. (2,0)) supersymmetry with 32 real supercharges which may be interpreted as the dimensional reduction of the chiral real 12-dimensional supersymmetry if its spacetime signature is (10,2). In (11,1) dimensions, the minimum number of components would be 64.The superfield C being a cocycle of the ordinary 4-differential cohomology on Calabi-Yau varietes of moduli spaces of line bundles which under decomposition into various cup product associated with a divisor of the CY4, yields intermediate Jacobians and Artin-Mazur formal groups of degrees of maximum three (0,1,2).

References

↑ Cumrun Vafa. "Evidence for F-theory." Nucl.Phys. B469: 403-418,1996 DOI:10.1016/0550-3213(96)00172-1. arXiv: hep-th/9602022
↑ Michio Kaku: The Universe Is a Symphony of Vibrating Strings - YouTube
↑ [1001.0577] Particle Physics Implications of F-theory

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F-theory

Compactifications

Phenomenology

Extra time dimensions

See also

References