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Complex spacetime

January 01, 1970

Complex spacetime is a mathematical framework that combines the concepts of complex numbers and spacetime in physics. In this framework, the usual real-valued coordinates of spacetime are replaced with complex-valued coordinates. This allows for the inclusion of imaginary components in the description of spacetime, which can have interesting implications in certain areas of physics, such as quantum field theory and string theory.

The notion is entirely mathematical with no physics implied, but should be seen as a tool, for instance, as exemplified by the Wick rotation.

Real and complex spaces edit

Mathematics edit

The complexification of a real vector space results in a complex vector space (over the complex number field). To "complexify" a space means extending ordinary scalar multiplication of vectors by real numbers to scalar multiplication by complex numbers. For complexified inner product spaces, the complex inner product on vectors replaces the ordinary real-valued inner product, an example of the latter being the dot product.

In mathematical physics, when we complexify a real coordinate space   we create a complex coordinate space  , referred to in differential geometry as a "complex manifold". The space   can be related to  , since every complex number constitutes two real numbers.

A complex spacetime geometry refers to the metric tensor being complex, not spacetime itself.

Physics edit

The Minkowski space of special relativity (SR) and general relativity (GR) is a 4 dimensional pseudo-Euclidean space. The spacetime underlying Albert Einstein's field equations, which mathematically describe gravitation, is a real 4 dimensional pseudo-Riemannian manifold.

In quantum mechanics, wave functions describing particles are complex-valued functions of real space and time variables. The set of all wavefunctions for a given system is an infinite-dimensional complex Hilbert space.

History edit

The notion of spacetime having more than four dimensions is of interest in its own mathematical right. Its appearance in physics can be rooted to attempts of unifying the fundamental interactions, originally gravity and electromagnetism. These ideas prevail in string theory and beyond. The idea of complex spacetime has received considerably less attention, but it has been considered in conjunction with the Lorentz–Dirac equation and the Maxwell equations.[1][2] Other ideas include mapping real spacetime into a complex representation space of SU(2, 2), see twistor theory.[3]

In 1919, Theodor Kaluza posted his 5-dimensional extension of general relativity, to Albert Einstein,[4] who was impressed with how the equations of electromagnetism emerged from Kaluza's theory. In 1926, Oskar Klein suggested[5] that Kaluza's extra dimension might be "curled up" into an extremely small circle, as if a circular topology is hidden within every point in space. Instead of being another spatial dimension, the extra dimension could be thought of as an angle, which created a hyper-dimension as it spun through 360°. This 5d theory is named Kaluza–Klein theory.

In 1932, Hsin P. Soh of MIT, advised by Arthur Eddington, published a theory attempting to unify gravitation and electromagnetism within a complex 4-dimensional Riemannian geometry. The line element ds2 is complex-valued, so that the real part corresponds to mass and gravitation, while the imaginary part with charge and electromagnetism. The usual space x, y, z and time t coordinates themselves are real and spacetime is not complex, but tangent spaces are allowed to be.[6]

For several decades after publishing his general theory of relativity in 1915, Albert Einstein tried to unify gravity with electromagnetism, to create a unified field theory explaining both interactions. In the latter years of World War II, Albert Einstein began considering complex spacetime geometries of various kinds.[7]

In 1953, Wolfgang Pauli generalised[8] the Kaluza–Klein theory to a six-dimensional space, and (using dimensional reduction) derived the essentials of an SU(2) gauge theory (applied in quantum mechanics to the electroweak interaction), as if Klein's "curled up" circle had become the surface of an infinitesimal hypersphere.

In 1975, Jerzy Plebanski published "Some Solutions of Complex Albert Einstein Equations".[9]

There have been attempts to formulate the Dirac equation in complex spacetime by analytic continuation.[10]

See also edit

References edit

  1. ^ Trautman, A. (1962). "A discussion on the present state of relativity - Analytic solutions of Lorentz-invariant linear equations". Proc. R. Soc. A. 270 (1342): 326–328. Bibcode:1962RSPSA.270..326T. doi:10.1098/rspa.1962.0222. S2CID 120301116.
  2. ^ Newman, E. T. (1973). "Maxwell's equations and complex Minkowski space". J. Math. Phys. 14 (1). The American Institute of Physics: 102–103. Bibcode:1973JMP....14..102N. doi:10.1063/1.1666160.
  3. ^ Penrose, Roger (1967), "Twistor algebra", Journal of Mathematical Physics, 8 (2): 345–366, Bibcode:1967JMP.....8..345P, doi:10.1063/1.1705200, MR 0216828, archived from the original on 2013-01-12, retrieved 2015-06-14
  4. ^ Pais, Abraham (1982). Subtle is the Lord ...: The Science and the Life of Albert Einstein. Oxford: Oxford University Press. pp. 329–330.
  5. ^ Oskar Klein (1926). "Quantentheorie und fünfdimensionale Relativitätstheorie". Zeitschrift für Physik A. 37 (12): 895–906. Bibcode:1926ZPhy...37..895K. doi:10.1007/BF01397481.
  6. ^ Soh, H. P. (1932). "A Theory of Gravitation and Electricity". J. Math. Phys. (MIT). 12 (1–4): 298–305. doi:10.1002/sapm1933121298.
  7. ^ Einstein, A. (1945), "A Generalization of the Relativistic Theory of Gravitation", Ann. of Math., 46 (4): 578–584, doi:10.2307/1969197, JSTOR 1969197
  8. ^ N. Straumann (2000). "On Pauli's invention of non-abelian Kaluza–Klein Theory in 1953". arXiv:gr-qc/0012054. Bibcode:2000gr.qc....12054S. {{cite journal}}: Cite journal requires |journal= (help)
  9. ^ Plebański, J. (1975). "Some solutions of complex Einstein equations". Journal of Mathematical Physics. 16 (12): 2395–2402. Bibcode:1975JMP....16.2395P. doi:10.1063/1.522505. S2CID 122814301.
  10. ^ Mark Davidson (2012). "A study of the Lorentz–Dirac equation in complex space-time for clues to emergent quantum mechanics". Journal of Physics: Conference Series. 361 (1): 012005. Bibcode:2012JPhCS.361a2005D. doi:10.1088/1742-6596/361/1/012005.

Further reading edit

  • Goenner, Hubert F.M. (2014). "On the history of unified field theories Part II (ca. 1930 — ca. 1965)". Living Reviews in Relativity. 17 (5): 5. Bibcode:2014LRR....17....5G. doi:10.12942/lrr-2014-5. PMC 5255905. PMID 28179849.
  • Kaiser, Gerald (2009). "Quantum Physics, Relativity, and Complex Spacetime: Towards a New Synthesis". arXiv:0910.0352 [math-ph].

January 01, 1970
complex, spacetime, mathematical, framework, that, combines, concepts, complex, numbers, spacetime, physics, this, framework, usual, real, valued, coordinates, spacetime, replaced, with, complex, valued, coordinates, this, allows, inclusion, imaginary, compone. Complex spacetime is a mathematical framework that combines the concepts of complex numbers and spacetime in physics In this framework the usual real valued coordinates of spacetime are replaced with complex valued coordinates This allows for the inclusion of imaginary components in the description of spacetime which can have interesting implications in certain areas of physics such as quantum field theory and string theory The notion is entirely mathematical with no physics implied but should be seen as a tool for instance as exemplified by the Wick rotation Contents 1 Real and complex spaces 1 1 Mathematics 1 2 Physics 2 History 3 See also 4 References 5 Further readingReal and complex spaces editMathematics edit The complexification of a real vector space results in a complex vector space over the complex number field To complexify a space means extending ordinary scalar multiplication of vectors by real numbers to scalar multiplication by complex numbers For complexified inner product spaces the complex inner product on vectors replaces the ordinary real valued inner product an example of the latter being the dot product In mathematical physics when we complexify a real coordinate space R n displaystyle mathbb R n nbsp we create a complex coordinate space C n displaystyle mathbb C n nbsp referred to in differential geometry as a complex manifold The space C n displaystyle mathbb C n nbsp can be related to R 2 n displaystyle mathbb R 2n nbsp since every complex number constitutes two real numbers A complex spacetime geometry refers to the metric tensor being complex not spacetime itself Physics edit The Minkowski space of special relativity SR and general relativity GR is a 4 dimensional pseudo Euclidean space The spacetime underlying Albert Einstein s field equations which mathematically describe gravitation is a real 4 dimensional pseudo Riemannian manifold In quantum mechanics wave functions describing particles are complex valued functions of real space and time variables The set of all wavefunctions for a given system is an infinite dimensional complex Hilbert space History editThe notion of spacetime having more than four dimensions is of interest in its own mathematical right Its appearance in physics can be rooted to attempts of unifying the fundamental interactions originally gravity and electromagnetism These ideas prevail in string theory and beyond The idea of complex spacetime has received considerably less attention but it has been considered in conjunction with the Lorentz Dirac equation and the Maxwell equations 1 2 Other ideas include mapping real spacetime into a complex representation space of SU 2 2 see twistor theory 3 In 1919 Theodor Kaluza posted his 5 dimensional extension of general relativity to Albert Einstein 4 who was impressed with how the equations of electromagnetism emerged from Kaluza s theory In 1926 Oskar Klein suggested 5 that Kaluza s extra dimension might be curled up into an extremely small circle as if a circular topology is hidden within every point in space Instead of being another spatial dimension the extra dimension could be thought of as an angle which created a hyper dimension as it spun through 360 This 5d theory is named Kaluza Klein theory In 1932 Hsin P Soh of MIT advised by Arthur Eddington published a theory attempting to unify gravitation and electromagnetism within a complex 4 dimensional Riemannian geometry The line element ds2 is complex valued so that the real part corresponds to mass and gravitation while the imaginary part with charge and electromagnetism The usual space x y z and time t coordinates themselves are real and spacetime is not complex but tangent spaces are allowed to be 6 For several decades after publishing his general theory of relativity in 1915 Albert Einstein tried to unify gravity with electromagnetism to create a unified field theory explaining both interactions In the latter years of World War II Albert Einstein began considering complex spacetime geometries of various kinds 7 In 1953 Wolfgang Pauli generalised 8 the Kaluza Klein theory to a six dimensional space and using dimensional reduction derived the essentials of an SU 2 gauge theory applied in quantum mechanics to the electroweak interaction as if Klein s curled up circle had become the surface of an infinitesimal hypersphere In 1975 Jerzy Plebanski published Some Solutions of Complex Albert Einstein Equations 9 There have been attempts to formulate the Dirac equation in complex spacetime by analytic continuation 10 See also editConstruction of a complex null tetrad Four vector Hilbert space Twistor space Spherical basis Riemann Silberstein vectorReferences edit Trautman A 1962 A discussion on the present state of relativity Analytic solutions of Lorentz invariant linear equations Proc R Soc A 270 1342 326 328 Bibcode 1962RSPSA 270 326T doi 10 1098 rspa 1962 0222 S2CID 120301116 Newman E T 1973 Maxwell s equations and complex Minkowski space J Math Phys 14 1 The American Institute of Physics 102 103 Bibcode 1973JMP 14 102N doi 10 1063 1 1666160 Penrose Roger 1967 Twistor algebra Journal of Mathematical Physics 8 2 345 366 Bibcode 1967JMP 8 345P doi 10 1063 1 1705200 MR 0216828 archived from the original on 2013 01 12 retrieved 2015 06 14 Pais Abraham 1982 Subtle is the Lord The Science and the Life of Albert Einstein Oxford Oxford University Press pp 329 330 Oskar Klein 1926 Quantentheorie und funfdimensionale Relativitatstheorie Zeitschrift fur Physik A 37 12 895 906 Bibcode 1926ZPhy 37 895K doi 10 1007 BF01397481 Soh H P 1932 A Theory of Gravitation and Electricity J Math Phys MIT 12 1 4 298 305 doi 10 1002 sapm1933121298 Einstein A 1945 A Generalization of the Relativistic Theory of Gravitation Ann of Math 46 4 578 584 doi 10 2307 1969197 JSTOR 1969197 N Straumann 2000 On Pauli s invention of non abelian Kaluza Klein Theory in 1953 arXiv gr qc 0012054 Bibcode 2000gr qc 12054S a href Template Cite journal html title Template Cite journal cite journal a Cite journal requires journal help Plebanski J 1975 Some solutions of complex Einstein equations Journal of Mathematical Physics 16 12 2395 2402 Bibcode 1975JMP 16 2395P doi 10 1063 1 522505 S2CID 122814301 Mark Davidson 2012 A study of the Lorentz Dirac equation in complex space time for clues to emergent quantum mechanics Journal of Physics Conference Series 361 1 012005 Bibcode 2012JPhCS 361a2005D doi 10 1088 1742 6596 361 1 012005 Further reading editGoenner Hubert F M 2014 On the history of unified field theories Part II ca 1930 ca 1965 Living Reviews in Relativity 17 5 5 Bibcode 2014LRR 17 5G doi 10 12942 lrr 2014 5 PMC 5255905 PMID 28179849 Kaiser Gerald 2009 Quantum Physics Relativity and Complex Spacetime Towards a New Synthesis arXiv 0910 0352 math ph Retrieved from https en wikipedia org w index php title Complex spacetime amp oldid 1184788057, wikipedia, wiki, book, books, library,

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