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Articles de revues sur le sujet « String: topological »

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Auteur : Grafiati

Publié le 14 mars 2023

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1

Tsai, Ya-Wen, Yao-Ting Wang, Pi-Gang Luan et Ta-Jen Yen. « Topological Phase Transition in a One-Dimensional Elastic String System ». Crystals 9, n^o 6 (18 juin 2019) : 313. http://dx.doi.org/10.3390/cryst9060313.

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We show that topological interface mode can emerge in a one-dimensional elastic string system which consists of two periodic strings with different band topologies. To verify their topological features, Zak-phase of each band is calculated and reveals the condition of topological phase transition accordingly. Apart from that, the transmittance spectrum illustrates that topological interface mode arises when two topologically distinct structures are connected. The vibration profile further exhibits the non-trivial interface mode in the domain wall between two periodic string composites.

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2

Sato, Matsuo, et Yuji Sugimoto. « Topological string geometry ». Nuclear Physics B 956 (juillet 2020) : 115019. http://dx.doi.org/10.1016/j.nuclphysb.2020.115019.

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3

Sugawara, Yuji. « Topological string on ». Nuclear Physics B 576, n^o 1-3 (juin 2000) : 265–84. http://dx.doi.org/10.1016/s0550-3213(00)00075-4.

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4

Derfoufi, Younes, et My Ismail Mamouni. « STRING TOPOLOGICAL ROBOTICS ». JP Journal of Geometry and Topology 19, n^o 3 (6 octobre 2016) : 189–208. http://dx.doi.org/10.17654/gt019030189.

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5

Curio, Gottfried. « Topological partition function and string-string duality ». Physics Letters B 366, n^o 1-4 (janvier 1996) : 131–33. http://dx.doi.org/10.1016/0370-2693(95)01347-4.

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6

Ayoub, Ettaki, My Ismail Mamouni et Mohamed Abdou Elomary. « STRING TOPOLOGICAL ROBOTICS 2 ». JP Journal of Algebra, Number Theory and Applications 58 (24 septembre 2022) : 1–18. http://dx.doi.org/10.17654/0972555522031.

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7

Chen, Shu. « Introduction to Mirror Symmetry in Aspects of Topological String Theory ». Journal of Physics : Conference Series 2386, n^o 1 (1 décembre 2022) : 012079. http://dx.doi.org/10.1088/1742-6596/2386/1/012079.

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Abstract Under the compactification by the Calabi-Yau threefold, the string theory shows there is duality called mirror symmetry, which implies there is an isomorphism between two string theories under the compactifications of two topologically different internal manifolds. By twisting the topological string theory in two methods, the twisted theories named A-model and B-model have an isomorphism to each other under the mirror symmetry.

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8

Segal, G. « Topological structures in string theory ». Philosophical Transactions of the Royal Society of London. Series A : Mathematical, Physical and Engineering Sciences 359, n^o 1784 (15 juillet 2001) : 1389–98. http://dx.doi.org/10.1098/rsta.2001.0841.

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9

Okuda, Takuya. « BIons in topological string theory ». Journal of High Energy Physics 2008, n^o 01 (28 janvier 2008) : 062. http://dx.doi.org/10.1088/1126-6708/2008/01/062.

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10

Antoniadis, I., E. Gava, K. S. Narain et T. R. Taylor. « Topological amplitudes in string theory ». Nuclear Physics B 413, n^o 1-2 (janvier 1994) : 162–84. http://dx.doi.org/10.1016/0550-3213(94)90617-3.

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11

Grassi, Alba, Johan Källén et Marcos Mariño. « The Topological Open String Wavefunction ». Communications in Mathematical Physics 338, n^o 2 (12 mai 2015) : 533–61. http://dx.doi.org/10.1007/s00220-015-2387-8.

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12

ZAIKOV, R. P. « BOSONIC STRING WITH TOPOLOGICAL TERM ». Modern Physics Letters A 06, n^o 16 (30 mai 1991) : 1453–57. http://dx.doi.org/10.1142/s0217732391001561.

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It is shown that in D = 3 space-time dimensions there exist a topological term for the bosonic strings. The corresponding constraints satisfy the same Virasoro algebra as the ordinary bosonic strings. These results are generalized for an arbitrary dimensional space-time if we have SO (1, 2) ⊗ O (D − 3) or SO (3) ⊗ O (1, D − 4) symmetry instead of SO (1, D − 1) space-time symmetry. A gauge-dependent correction to the Casimir energy corresponding to this topological term is derived.

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13

Balachandran, A. P., F. Lizzi, R. D. Sorkin et G. Sparano. « Topological aspects of string theories ». Nuclear Physics B 287 (janvier 1987) : 508–50. http://dx.doi.org/10.1016/0550-3213(87)90116-7.

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14

ISHIKAWA, HIROSHI, et MITSUHIRO KATO. « NOTE ON N = 0 STRING AS N = 1 STRING ». Modern Physics Letters A 09, n^o 08 (14 mars 1994) : 725–28. http://dx.doi.org/10.1142/s0217732394000538.

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A similarity transformation, which brings a particular class of N = 1 strings to those with N = 0, is explicitly constructed. It enables us to give a simple proof for the argument recently proposed by Berkovits and Vafa. The N = 1 BRST operator is turned into the direct sum of the corresponding N = 0 BRST operator and that for an additional topological sector. As a result, the physical spectrum of these N = 1 vacua is shown to be isomorphic to the tensor product of the N = 0 spectrum and the topological sector which consists of only the vacuum. This transformation manifestly keeps the operator algebra.

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15

DUAN, YI-SHI, LI-DA ZHANG et YU-XIAO LIU. « A NEW DESCRIPTION OF COSMIC STRINGS IN BRANE WORLD SCENARIO ». Modern Physics Letters A 23, n^o 24 (10 août 2008) : 2023–30. http://dx.doi.org/10.1142/s021773230802611x.

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In the light of ϕ-mapping topological current theory, the structure of cosmic strings are obtained from the Abelian Higgs model, which is an effective description to the brane world cosmic string system. In this topological description of the cosmic string, combining the result of decomposition of U(1) gauge potential, we analytically reach the familiar conclusions that in the brane world scenario the magnetic flux of the cosmic string is quantized and the RR charge of it is screened.

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16

BALACHANDRAN, A. P., W. D. McGLINN, L. O’RAIFEARTAIGH, S. SEN, R. D. SORKIN et A. M. SRIVASTAVA. « TOPOLOGICAL SPIN-STATISTICS THEOREMS FOR STRINGS ». Modern Physics Letters A 07, n^o 16 (30 mai 1992) : 1427–42. http://dx.doi.org/10.1142/s0217732392001105.

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Recently, a topological proof of the spin-statistics theorem has been proposed for a system of point particles. It does not require relativity or field theory, but assumes the existence of antiparticles. We extend this proof to a system of string loops in three space dimensions and show that by assuming the existence of antistring loops, one can prove a spin-statistics theorem for these string loops. According to this theorem, all unparametrized strings (such as flux tubes in superconductors and cosmic strings) should be quantized as bosons. Also, as in the point particle case, we find that the theorem excludes non-Abelian statistics.

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17

HIRANO, SHINJI, et HIROSHI ISHIKAWA. « TOPOLOGICAL STRUCTURE IN $\hat c =1$ FERMIONIC STRING THEORY ». Modern Physics Letters A 09, n^o 33 (30 octobre 1994) : 3077–87. http://dx.doi.org/10.1142/s0217732394002902.

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[Formula: see text] fermionic string theory, which is considered as a fermionic string theory in two dimensions, is shown to decompose into two mutually independent parts, one of which can be viewed as a topological model and the other is irrelevant for the theory. The physical contents of the theory is largely governed by this topological structure, and the discrete physical spectrum of [Formula: see text] string theory is naturally explained as the physical spectrum of the topological model. This topological structure turns out to be related with a novel hidden N = 2 superconformal algebra (SCA) in the enveloping algebra of the N = 3 SCA in fermionic string theories.

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18

Costello, Kevin, et Si Li. « Anomaly cancellation in the topological string ». Advances in Theoretical and Mathematical Physics 24, n^o 7 (2020) : 1723–71. http://dx.doi.org/10.4310/atmp.2020.v24.n7.a2.

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19

Cook, Paul L. H., Hirosi Ooguri et Jie Yang. « New Anomalies in Topological String Theory ». Progress of Theoretical Physics Supplement 177 (2009) : 120–27. http://dx.doi.org/10.1143/ptps.177.120.

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20

Ezawa, Z. F., S. Nakamura et A. Tezuka. « Topological solitons and compactified bosonic string ». Physical Review D 34, n^o 12 (15 décembre 1986) : 3805–10. http://dx.doi.org/10.1103/physrevd.34.3805.

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21

Yamaguchi, Satoshi, et Shing-Tung Yau. « Topological String Partition Functions as Polynomials ». Journal of High Energy Physics 2004, n^o 07 (22 juillet 2004) : 047. http://dx.doi.org/10.1088/1126-6708/2004/07/047.

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22

Bouchard, Vincent, Bogdan Florea et Marcos Marino. « Topological Open String Amplitudes On Orientifolds ». Journal of High Energy Physics 2005, n^o 02 (3 février 2005) : 002. http://dx.doi.org/10.1088/1126-6708/2005/02/002.

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23

Grimm, Thomas W., Albrecht Klemm, Marcos Mariño et Marlene Weiss. « Direct integration of the topological string ». Journal of High Energy Physics 2007, n^o 08 (20 août 2007) : 058. http://dx.doi.org/10.1088/1126-6708/2007/08/058.

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24

Hyun, Seungjoon, Kyungho Oh, Jong-Dae Park et Sang-Heon Yi. « Topological B-model and string theory ». Nuclear Physics B 729, n^o 1-2 (novembre 2005) : 135–62. http://dx.doi.org/10.1016/j.nuclphysb.2005.08.048.

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25

Antoniadis, I., S. Hohenegger et K. S. Narain. « topological amplitudes and string effective action ». Nuclear Physics B 771, n^o 1-2 (mai 2007) : 40–92. http://dx.doi.org/10.1016/j.nuclphysb.2007.02.011.

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26

Nag, Subhashis, et Parameswaran Sankaran. « Open string diagrams I : Topological type ». Journal of Mathematical Physics 34, n^o 10 (octobre 1993) : 4562–74. http://dx.doi.org/10.1063/1.530357.

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27

Klemm, A. « Topological string theory and integrable structures ». Fortschritte der Physik 53, n^o 7-8 (15 juillet 2005) : 720–69. http://dx.doi.org/10.1002/prop.200410235.

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28

Morse, Jack, et Rolf Schimmrigk. « Topological phases of the heterotic string ». Physics Letters B 278, n^o 1-2 (mars 1992) : 97–100. http://dx.doi.org/10.1016/0370-2693(92)90718-j.

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29

Liu, Zhengwei, Alex Wozniakowski et Arthur M. Jaffe. « Quon 3D language for quantum information ». Proceedings of the National Academy of Sciences 114, n^o 10 (6 février 2017) : 2497–502. http://dx.doi.org/10.1073/pnas.1621345114.

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We present a 3D topological picture-language for quantum information. Our approach combines charged excitations carried by strings, with topological properties that arise from embedding the strings in the interior of a 3D manifold with boundary. A quon is a composite that acts as a particle. Specifically, a quon is a hemisphere containing a neutral pair of open strings with opposite charge. We interpret multiquons and their transformations in a natural way. We obtain a type of relation, a string–genus “joint relation,” involving both a string and the 3D manifold. We use the joint relation to obtain a topological interpretation of theC∗-Hopf algebra relations, which are widely used in tensor networks. We obtain a 3D representation of the controlled NOT (CNOT) gate that is considerably simpler than earlier work, and a 3D topological protocol for teleportation.

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30

Li, Xinfei, Xin Liu et Yong-Chang Huang. « Tackling tangledness of cosmic strings by knot polynomial topological invariants ». International Journal of Modern Physics A 32, n^o 27 (30 septembre 2017) : 1750164. http://dx.doi.org/10.1142/s0217751x17501640.

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Cosmic strings in the early universe have received revived interest in recent years. In this paper, we derive these structures as topological defects from singular distributions of the quintessence field of dark energy. Our emphasis is placed on the topological charge of tangled cosmic strings, which originates from the Hopf mapping and is a Chern–Simons action possessing strong inherent tie to knot topology. It is shown that the Kauffman bracket knot polynomial can be constructed in terms of this charge for unoriented knotted strings, serving as a topological invariant much stronger than the traditional Gauss linking numbers in characterizing string topology. Especially, we introduce a mathematical approach of breaking-reconnection which provides a promising candidate for studying physical reconnection processes within the complexity-reducing cascades of tangled cosmic strings.

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31

Jia, Bei. « Topological string theory revisited I : The stage ». International Journal of Modern Physics A 31, n^o 24 (30 août 2016) : 1650135. http://dx.doi.org/10.1142/s0217751x16501359.

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In this paper, we reformulate topological string theory using supermanifolds and supermoduli spaces, following the approach worked out by Witten (Superstring perturbation theory revisited, arXiv:1209.5461 ). We intend to make the construction geometrical in nature, by using supergeometry techniques extensively. The goal is to establish the foundation of studying topological string amplitudes in terms of integration over appropriate supermoduli spaces.

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32

Achúcarro, A., A. Avgoustidis, A. López-Eiguren, C. J. A. P. Martins et J. Urrestilla. « Cosmological evolution of semilocal string networks ». Philosophical Transactions of the Royal Society A : Mathematical, Physical and Engineering Sciences 377, n^o 2161 (11 novembre 2019) : 20190004. http://dx.doi.org/10.1098/rsta.2019.0004.

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Semilocal strings—a particular limit of electroweak strings—are an interesting example of a stable non-topological defect whose properties resemble those of their topological cousins, the Abrikosov–Nielsen–Olesen vortices. There is, however, one important difference: a network of semilocal strings will contain segments. These are ‘dumbbells’ whose ends behave almost like global monopoles that are strongly attracted to one another. While closed loops of string will eventually shrink and disappear, the segments can either shrink or grow, and a cosmological network of semilocal strings will reach a scaling regime. We discuss attempts to find a ‘thermodynamic’ description of the cosmological evolution and scaling of a network of semilocal strings, by analogy with well-known descriptions for cosmic strings and for monopoles. We propose a model for the time evolution of an overall length scale and typical velocity for the network as well as for its segments, and some supporting (preliminary) numerical evidence. This article is part of a discussion meeting issue ‘Topological avatars of new physics’.

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33

Morgan, MJ, et Tan Tat Hin. « Topological Effects of a Circular Cosmic String ». Australian Journal of Physics 49, n^o 3 (1996) : 607. http://dx.doi.org/10.1071/ph960607.

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The behaviour of a quantum particle in the spacetime region exterior to a circular cosmic string is studied by constructing a connection one-form in the tetrad formalism. In the weak-field approximation, near the string core, the space exhibits a conical singularity, with an attendant topological phase and distortion of the energy spectrum of a scalar particle determined by the global properties of the spacetime structure of the string loop.

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34

Mariño, Marcos. « Open string amplitudes and large order behavior in topological string theory ». Journal of High Energy Physics 2008, n^o 03 (25 mars 2008) : 060. http://dx.doi.org/10.1088/1126-6708/2008/03/060.

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35

ISHIKAWA, HIROSHI, et MITSUHIRO KATO. « c=1 STRING AS A TOPOLOGICAL MODEL ». International Journal of Modern Physics A 09, n^o 32 (30 décembre 1994) : 5769–89. http://dx.doi.org/10.1142/s0217751x94002387.

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The discrete states in the c=1 string are shown to be the physical states of a certain topological sigma model. We define a set of new fields directly from c=1 variables, in terms of which the BRST charge and energy-momentum tensor are rewritten as those of the topological sigma model. Remarkably, ground ring generator x turns out to be a coordinate of the sigma model. All of the discrete states realize a graded ring which contains the ground ring as a subset.

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36

Saidi, El Hassan, et Moulay Brahim Sedra. « Topological string in harmonic space and correlation functions in stringy cosmology ». Nuclear Physics B 748, n^o 3 (août 2006) : 380–457. http://dx.doi.org/10.1016/j.nuclphysb.2006.04.020.

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37

Sakamoto, M., et M. Tachibana. « Topological Terms in String Theory on Orbifolds ». Progress of Theoretical Physics 93, n^o 2 (1 février 1995) : 471–81. http://dx.doi.org/10.1143/ptp.93.471.

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38

Carqueville, Nils. « Matrix factorisations and open topological string theory ». Journal of High Energy Physics 2009, n^o 07 (2 juillet 2009) : 005. http://dx.doi.org/10.1088/1126-6708/2009/07/005.

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39

Gasparim, Elizabeth, Bruno Suzuki, Alexander Torres-Gomez et Carlos A. B. Varea. « Topological string partition function on generalised conifolds ». Journal of Mathematical Physics 58, n^o 4 (avril 2017) : 042303. http://dx.doi.org/10.1063/1.4980013.

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40

Antoniadis, I., I. Florakis, S. Hohenegger, K. S. Narain et A. Zein Assi. « Worldsheet realization of the refined topological string ». Nuclear Physics B 875, n^o 1 (octobre 2013) : 101–33. http://dx.doi.org/10.1016/j.nuclphysb.2013.07.004.

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41

Ramadevi, P., et Tapobrata Sarkar. « On link invariants and topological string amplitudes ». Nuclear Physics B 600, n^o 3 (avril 2001) : 487–511. http://dx.doi.org/10.1016/s0550-3213(00)00761-6.

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42

Antoniadis, I., K. S. Narain et T. R. Taylor. « Open string topological amplitudes and gaugino masses ». Nuclear Physics B 729, n^o 1-2 (novembre 2005) : 235–77. http://dx.doi.org/10.1016/j.nuclphysb.2005.09.024.

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43

Cattaneo, Alberto S., Jürg Fröhlich et Bill Pedrini. « Topological Field Theory Interpretation of String Topology ». Communications in Mathematical Physics 240, n^o 3 (19 août 2003) : 397–421. http://dx.doi.org/10.1007/s00220-003-0917-2.

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44

Mathai, Varghese, Guo Chuan Thiang, Pedram Hekmati, Henriques Bursztyn, Peter Bouwknegt et David Baraglia. « Foreword : String geometries, dualities and topological matter ». Journal of Geometry and Physics 138 (avril 2019) : 331–32. http://dx.doi.org/10.1016/j.geomphys.2018.06.004.

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45

Oz, Yaron. « On topological 2D string and intersection theory ». Physics Letters B 355, n^o 1-2 (juillet 1995) : 135–40. http://dx.doi.org/10.1016/0370-2693(95)00740-c.

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46

Carqueville, Nils, et Michael M. Kay. « Bulk Deformations of Open Topological String Theory ». Communications in Mathematical Physics 315, n^o 3 (24 juin 2012) : 739–69. http://dx.doi.org/10.1007/s00220-012-1513-0.

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47

Russo, Jorge G. « Topological invariants in non-critical string theories ». Physics Letters B 262, n^o 4 (juin 1991) : 411–18. http://dx.doi.org/10.1016/0370-2693(91)90614-v.

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48

Balitsky, Ianko I., et Vladimir M. Braun. « Topological current Kμ as a string operator ». Physics Letters B 267, n^o 3 (septembre 1991) : 405–10. http://dx.doi.org/10.1016/0370-2693(91)90954-o.

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49

Li, Jun, Kefeng Liu et Jian Zhou. « Topological String Partition Functions as Equivariant Indices ». Asian Journal of Mathematics 10, n^o 1 (2006) : 81–114. http://dx.doi.org/10.4310/ajm.2006.v10.n1.a6.

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50

de Boer, Jan, Asad Naqvi et Assaf Shomer. « The Topological G₂ String ». Advances in Theoretical and Mathematical Physics 12, n^o 2 (2008) : 243–318. http://dx.doi.org/10.4310/atmp.2008.v12.n2.a2.

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