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Artículos de revistas sobre el tema "Quantum field theory"

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Publicado: 4 de junio de 2021
Última modificación: 30 de julio de 2024

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1

Hofmann, Ralf. "Quantum Field Theory". Universe 10, n.º 1 (28 de diciembre de 2023): 14. http://dx.doi.org/10.3390/universe10010014.

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This Special Issue on quantum field theory presents work covering a wide and topical range of subjects mainly within the area of interacting 4D quantum field theories subject to certain backgrounds [...]
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2

Hudson, R. L. y L. S. Brown. "Quantum Field Theory". Mathematical Gazette 79, n.º 484 (marzo de 1995): 249. http://dx.doi.org/10.2307/3620134.

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3

Wilczek, Frank. "Quantum field theory". Reviews of Modern Physics 71, n.º 2 (1 de marzo de 1999): S85—S95. http://dx.doi.org/10.1103/revmodphys.71.s85.

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4

Collins, P. D. B. "Quantum Field Theory". Physics Bulletin 36, n.º 9 (septiembre de 1985): 391. http://dx.doi.org/10.1088/0031-9112/36/9/028.

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5

Mandl, F., G. Shaw y Stephen Gasiorowicz. "Quantum Field Theory". Physics Today 38, n.º 10 (octubre de 1985): 111–12. http://dx.doi.org/10.1063/1.2814741.

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6

Collins, P. D. B. "Quantum Field Theory". Physics Bulletin 37, n.º 7 (julio de 1986): 304. http://dx.doi.org/10.1088/0031-9112/37/7/030.

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7

Unger, H. J. "Quantum Field Theory". Zeitschrift für Physikalische Chemie 187, Part_1 (enero de 1994): 155–56. http://dx.doi.org/10.1524/zpch.1994.187.part_1.155a.

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8

Uhlmann, A. "Quantum Field Theory". Zeitschrift für Physikalische Chemie 194, Part_1 (enero de 1996): 130. http://dx.doi.org/10.1524/zpch.1996.194.part_1.130.

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9

Brown, Lowell S., Michio Kaku y O. W. Greenberg. "Quantum Field Theory and Quantum Field Theory: A Modern Introduction". Physics Today 47, n.º 2 (febrero de 1994): 104–6. http://dx.doi.org/10.1063/1.2808409.

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10

Frolov, P. A. y A. V. Shebeko. "Relativistic Invariance and Mass Renormalization in Quantum Field Theory". Ukrainian Journal of Physics 59, n.º 11 (noviembre de 2014): 1060–64. http://dx.doi.org/10.15407/ujpe59.11.1060.

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11

SCHLINGEMANN, DIRK. "FROM EUCLIDEAN FIELD THEORY TO QUANTUM FIELD THEORY". Reviews in Mathematical Physics 11, n.º 09 (octubre de 1999): 1151–78. http://dx.doi.org/10.1142/s0129055x99000362.

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In order to construct examples for interacting quantum field theory models, the methods of Euclidean field theory turned out to be powerful tools since they make use of the techniques of classical statistical mechanics. Starting from an appropriate set of Euclidean n-point functions (Schwinger distributions), a Wightman theory can be reconstructed by an application of the famous Osterwalder–Schrader reconstruction theorem. This procedure (Wick rotation), which relates classical statistical mechanics and quantum field theory, is, however, somewhat subtle. It relies on the analytic properties of the Euclidean n-point functions. We shall present here a C*-algebraic version of the Osterwalder–Schrader reconstruction theorem. We shall see that, via our reconstruction scheme, a Haag–Kastler net of bounded operators can directly be reconstructed. Our considerations also include objects, like Wilson loop variables, which are not point-like localized objects like distributions. This point of view may also be helpful for constructing gauge theories.
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12

STERMAN, GEORGE. "PERTURBATIVE QUANTUM FIELD THEORY". International Journal of Modern Physics A 16, n.º 18 (20 de julio de 2001): 3041–65. http://dx.doi.org/10.1142/s0217751x01004402.

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This talk introduces perturbative quantum field on a heuristic level. It is directed at an audience familiar with elements of quantum mechanics, but not necessarily with high energy physics. It includes a discussion of the strategies behind experimental tests of fundamental theories, and of the field theory interpretations of these tests.
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13

Doplicher, Sergio. "Quantum Field Theory on Quantum Spacetime". Journal of Physics: Conference Series 53 (1 de noviembre de 2006): 793–98. http://dx.doi.org/10.1088/1742-6596/53/1/051.

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14

UBRIACO, MARCELO R. "QUANTUM GROUP SCHRÖDINGER FIELD THEORY". Modern Physics Letters A 08, n.º 23 (30 de julio de 1993): 2213–21. http://dx.doi.org/10.1142/s021773239300194x.

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We show that a quantum deformation of quantum mechanics given in a previous work is equivalent to quantum mechanics on a nonlinear lattice with step size ∆x=(1−q)x. Then, based on this, we develop the basic formalism of quantum group Schrödinger field theory in one spatial quantum dimension, and explicitly exhibit the SU q(2) covariant algebras satisfied by the q-bosonic and q-fermionic Schrödinger fields. We generalize this result to an arbitrary number of fields.
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15

Potvin, Jean, Harvey Gould y Jan Tobochnik. "Computational Quantum-Field Theory". Computers in Physics 7, n.º 2 (1993): 149. http://dx.doi.org/10.1063/1.4823157.

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16

Adler, Stephen L. "Quaternionic Quantum Field Theory". Physical Review Letters 55, n.º 13 (23 de septiembre de 1985): 1430. http://dx.doi.org/10.1103/physrevlett.55.1430.2.

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17

Adler, Stephen L. "Quaternionic Quantum Field Theory". Physical Review Letters 55, n.º 8 (19 de agosto de 1985): 783–86. http://dx.doi.org/10.1103/physrevlett.55.783.

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18

Brandt, Howard E. "Finslerian quantum field theory". Nonlinear Analysis: Theory, Methods & Applications 63, n.º 5-7 (noviembre de 2005): e119-e130. http://dx.doi.org/10.1016/j.na.2005.02.085.

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19

Ruetsche, Laura. "Interpreting Quantum Field Theory*". Philosophy of Science 69, n.º 2 (junio de 2002): 348–78. http://dx.doi.org/10.1086/341047.

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20

Oeckl, Robert. "Braided Quantum Field Theory". Communications in Mathematical Physics 217, n.º 2 (1 de marzo de 2001): 451–73. http://dx.doi.org/10.1007/s002200100375.

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21

Alder, Stephen L. "Quaternionic quantum field theory". Communications in Mathematical Physics 104, n.º 4 (diciembre de 1986): 611–56. http://dx.doi.org/10.1007/bf01211069.

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22

W.F.A. "Renormalized quantum field theory". Mathematics and Computers in Simulation 33, n.º 2 (agosto de 1991): 177. http://dx.doi.org/10.1016/0378-4754(91)90169-4.

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23

Bejleri, Dori y Matilde Marcolli. "Quantum field theory overF1". Journal of Geometry and Physics 69 (julio de 2013): 40–59. http://dx.doi.org/10.1016/j.geomphys.2013.03.002.

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24

Freed, Daniel S. y Constantin Teleman. "Relative Quantum Field Theory". Communications in Mathematical Physics 326, n.º 2 (31 de enero de 2014): 459–76. http://dx.doi.org/10.1007/s00220-013-1880-1.

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25

HAAG, RUDOLF. "UNDERSTANDING QUANTUM FIELD THEORY". International Journal of Modern Physics B 10, n.º 13n14 (30 de junio de 1996): 1469–72. http://dx.doi.org/10.1142/s021797929600057x.

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26

Streater, Raymond. "Wightman quantum field theory". Scholarpedia 4, n.º 5 (2009): 7123. http://dx.doi.org/10.4249/scholarpedia.7123.

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27

Münster, Gernot. "Lattice quantum field theory". Scholarpedia 5, n.º 12 (2010): 8613. http://dx.doi.org/10.4249/scholarpedia.8613.

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28

Jaffe, Arthur. "Euclidean quantum field theory". Nuclear Physics B 254 (enero de 1985): 31–43. http://dx.doi.org/10.1016/0550-3213(85)90208-1.

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29

Rohrlich, Fritz. "Interpreting quantum field theory". Studies in History and Philosophy of Science Part B: Studies in History and Philosophy of Modern Physics 27, n.º 1 (marzo de 1996): 91–98. http://dx.doi.org/10.1016/1355-2198(95)00024-0.

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30

Witten, Edward. "Topological quantum field theory". Communications in Mathematical Physics 117, n.º 3 (septiembre de 1988): 353–86. http://dx.doi.org/10.1007/bf01223371.

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31

Grosse, H. y R. Wulkenhaar. "Noncommutative quantum field theory". Fortschritte der Physik 62, n.º 9-10 (4 de julio de 2014): 797–811. http://dx.doi.org/10.1002/prop.201400020.

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32

Gurau, Razvan, Jacques Magnen y Vincent Rivasseau. "Tree Quantum Field Theory". Annales Henri Poincaré 10, n.º 5 (25 de julio de 2009): 867–91. http://dx.doi.org/10.1007/s00023-009-0002-2.

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33

APFELDORF, KARYN M., HORACIO E. CAMBLONG y CARLOS R. ORDÓÑEZ. "FIELD REDEFINITION INVARIANCE IN QUANTUM FIELD THEORY". Modern Physics Letters A 16, n.º 03 (30 de enero de 2001): 103–12. http://dx.doi.org/10.1142/s021773230100319x.

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The issue of field redefinition invariance of path integrals in quantum field theory is re-examined. A "paradox" is presented involving the reduction to an effective quantum-mechanical theory of a (d+1)-dimensional free scalar field in a Minkowskian space–time with compactified spatial coordinates. The implementation of field redefinitions both before and after the reduction suggests that operator-ordering issues in quantum field theory should not be ignored.
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34

Freed, D. S. "K-theory in quantum field theory". Current Developments in Mathematics 2001, n.º 1 (2001): 41–887. http://dx.doi.org/10.4310/cdm.2001.v2001.n1.a2.

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35

BENDER, CARL M. "NON-HERMITIAN QUANTUM FIELD THEORY". International Journal of Modern Physics A 20, n.º 19 (30 de julio de 2005): 4646–52. http://dx.doi.org/10.1142/s0217751x05028326.

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In my talk at the Seventh QCD Workshop held in Villefranche in January 2003 I showed that a non-Hermitian Hamiltonian H possessing an unbroken [Formula: see text] symmetry (i) has a real spectrum that is bounded below, and (ii) defines a unitary theory of quantum mechanics with positive norm. The proof of unitarity requires a linear operator [Formula: see text], which was originally defined as a sum over the eigenfunctions of H. However, using this definition to calculate [Formula: see text] is cumbersome in quantum mechanics and impossible in quantum field theory. I describe here an alternative method for calculating [Formula: see text] directly in terms of the operator dynamical variables of the quantum theory. This new method is general and applies to a variety of quantum mechanical systems having several degrees of freedom. More importantly, this method gives the [Formula: see text] operator in quantum field theory. The [Formula: see text] operator is a new time-independent observable in [Formula: see text]-symmetric quantum field theory.
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36

Lori, Nicolás, José Neves y José Machado. "Quantum Field Theory Representation in Quantum Computation". Applied Sciences 11, n.º 23 (28 de noviembre de 2021): 11272. http://dx.doi.org/10.3390/app112311272.

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Recently, from the deduction of the result MIP* = RE in quantum computation, it was obtained that Quantum Field Theory (QFT) allows for different forms of computation in quantum computers that Quantum Mechanics (QM) does not allow. Thus, there must exist forms of computation in the QFT representation of the Universe that the QM representation does not allow. We explain in a simple manner how the QFT representation allows for different forms of computation by describing the differences between QFT and QM, and obtain why the future of quantum computation will require the use of QFT.
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37

Gogioso, Stefano y Fabrizio Genovese. "Quantum Field Theory in Categorical Quantum Mechanics". Electronic Proceedings in Theoretical Computer Science 287 (31 de enero de 2019): 163–77. http://dx.doi.org/10.4204/eptcs.287.9.

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38

Calcagni, Gianluca, Leonardo Modesto y Giuseppe Nardelli. "Quantum spectral dimension in quantum field theory". International Journal of Modern Physics D 25, n.º 05 (abril de 2016): 1650058. http://dx.doi.org/10.1142/s0218271816500589.

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We reinterpret the spectral dimension of spacetimes as the scaling of an effective self-energy transition amplitude in quantum field theory (QFT), when the system is probed at a given resolution. This picture has four main advantages: (a) it dispenses with the usual interpretation (unsatisfactory in covariant approaches) where, instead of a transition amplitude, one has a probability density solving a nonrelativistic diffusion equation in an abstract diffusion time; (b) it solves the problem of negative probabilities known for higher-order and nonlocal dispersion relations in classical and quantum gravity; (c) it clarifies the concept of quantum spectral dimension as opposed to the classical one. We then consider a class of logarithmic dispersion relations associated with quantum particles and show that the spectral dimension [Formula: see text] of spacetime as felt by these quantum probes can deviate from its classical value, equal to the topological dimension [Formula: see text]. In particular, in the presence of higher momentum powers it changes with the scale, dropping from [Formula: see text] in the infrared (IR) to a value [Formula: see text] in the ultraviolet (UV). We apply this general result to Stelle theory of renormalizable gravity, which attains the universal value [Formula: see text] for any dimension [Formula: see text].
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39

Barrett, John W. "Quantum gravity as topological quantum field theory". Journal of Mathematical Physics 36, n.º 11 (noviembre de 1995): 6161–79. http://dx.doi.org/10.1063/1.531239.

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40

Balachandran, A. P. "Localization in quantum field theory". International Journal of Geometric Methods in Modern Physics 14, n.º 08 (11 de mayo de 2017): 1740008. http://dx.doi.org/10.1142/s0219887817400084.

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In non-relativistic quantum mechanics, Born’s principle of localization is as follows: For a single particle, if a wave function [Formula: see text] vanishes outside a spatial region [Formula: see text], it is said to be localized in [Formula: see text]. In particular, if a spatial region [Formula: see text] is disjoint from [Formula: see text], a wave function [Formula: see text] localized in [Formula: see text] is orthogonal to [Formula: see text]. Such a principle of localization does not exist compatibly with relativity and causality in quantum field theory (QFT) (Newton and Wigner) or interacting point particles (Currie, Jordan and Sudarshan). It is replaced by symplectic localization of observables as shown by Brunetti, Guido and Longo, Schroer and others. This localization gives a simple derivation of the spin-statistics theorem and the Unruh effect, and shows how to construct quantum fields for anyons and for massless particles with “continuous” spin. This review outlines the basic principles underlying symplectic localization and shows or mentions its deep implications. In particular, it has the potential to affect relativistic quantum information theory and black hole physics.
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41

FIALKOVSKY, I. V. y D. V. VASSILEVICH. "QUANTUM FIELD THEORY IN GRAPHENE". International Journal of Modern Physics: Conference Series 14 (enero de 2012): 88–99. http://dx.doi.org/10.1142/s2010194512007258.

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This is a short non-technical introduction to applications of the Quantum Field Theory methods to graphene. We derive the Dirac model from the tight binding model and describe calculations of the polarization operator (conductivity). Later on, we use this quantity to describe the Quantum Hall Effect, light absorption by graphene, the Faraday effect, and the Casimir interaction.
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42

FIALKOVSKY, I. V. y D. V. VASSILEVICH. "QUANTUM FIELD THEORY IN GRAPHENE". International Journal of Modern Physics A 27, n.º 15 (14 de junio de 2012): 1260007. http://dx.doi.org/10.1142/s0217751x1260007x.

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This is a short nontechnical introduction to applications of the Quantum Field Theory methods to graphene. We derive the Dirac model from the tight binding model and describe calculations of the polarization operator (conductivity). Later on, we use this quantity to describe the Quantum Hall Effect, light absorption by graphene, the Faraday effect, and the Casimir interaction.
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43

JANSEN, KARL. "LATTICE FIELD THEORY". International Journal of Modern Physics E 16, n.º 09 (octubre de 2007): 2638–79. http://dx.doi.org/10.1142/s0218301307008355.

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Starting with the example of the quantum mechanical harmonic oscillator, we develop the concept of euclidean lattice field theory. After describing Wilson's formulation of quantum chromodynamics on the lattice, we will introduce modern lattice QCD actions which greatly reduce lattice artefacts or are even chiral invariant. The substantial algorithmic improvements of the last couple of years will be shown which led to a real breakthrough for dynamical Wilson fermion simulations. Finally, we will present some results of present simulations with dynamical quarks and demonstrate that nowadays even at small values of the quark mass high precision simulation results for physical quantities can be obtained.
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44

Gracey, J. A. "Large Nf quantum field theory". International Journal of Modern Physics A 33, n.º 35 (20 de diciembre de 2018): 1830032. http://dx.doi.org/10.1142/s0217751x18300326.

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We review the development of the large [Formula: see text] method, where [Formula: see text] indicates the number of flavours, used to study perturbative and nonperturbative properties of quantum field theories. The relevant historical background is summarized as a prelude to the introduction of the large [Formula: see text] critical point formalism. This is used to compute large [Formula: see text] corrections to [Formula: see text]-dimensional critical exponents of the universal quantum field theory present at the Wilson–Fisher fixed point. While pedagogical in part the application to gauge theories is also covered and the use of the large [Formula: see text] method to complement explicit high order perturbative computations in gauge theories is also highlighted. The usefulness of the technique in relation to other methods currently used to study quantum field theories in [Formula: see text]-dimensions is also summarized.
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45

Baker, David John. "Against Field Interpretations of Quantum Field Theory". British Journal for the Philosophy of Science 60, n.º 3 (1 de septiembre de 2009): 585–609. http://dx.doi.org/10.1093/bjps/axp027.

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46

Arimitsu, T., M. Guida y H. Umezawa. "Dissipative quantum field theory -thermo field dynamics-". Physica A: Statistical Mechanics and its Applications 148, n.º 1-2 (febrero de 1988): 1–26. http://dx.doi.org/10.1016/0378-4371(88)90131-8.

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47

Coutinho, F. AB, D. Kiang, Y. Nogami y L. Tomio. "Dirac's hole theory versus quantum field theory". Canadian Journal of Physics 80, n.º 8 (1 de agosto de 2002): 837–45. http://dx.doi.org/10.1139/p02-048.

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Dirac's hole theory and quantum field theory are usually considered equivalent to each other. The equivalence, however, does not necessarily hold, as we discuss in terms of models of a certain type. We further suggest that the equivalence may fail in more general models. This problem is closely related to the validity of the Pauli principle in intermediate states of perturbation theory. PACS Nos.: 03.65-w, 11.10-z, 11.15Bt, 12.39Ba
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48

Pospisil, Christina. "Book Review: Quantum Field Theory". Physics International 12, n.º 1 (1 de enero de 2021): 1. http://dx.doi.org/10.3844/pisp.2021.1.1.

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49

Borcherds, Richard. "Renormalization and quantum field theory". Algebra & Number Theory 5, n.º 5 (31 de diciembre de 2011): 627–58. http://dx.doi.org/10.2140/ant.2011.5.627.

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50

Carvalho, C. A. A. de. "Summary talk: quantum field theory". Brazilian Journal of Physics 34, n.º 1a (marzo de 2004): 224–25. http://dx.doi.org/10.1590/s0103-97332004000200014.

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