Quantum Field Theory and Gravity: Conceptual and Mathematical ...

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The Same Physics in All Spacetimes 225 with compact spatial section (see, for example [19]). The same problem afflicts the massless scalar field in two-dimensional Minkowski space, whereitiscommonplacetorejectthealgebraoffieldsinfavourofthe algebra of currents. • The nonminimally coupled scalar field (which does not have the gauge symmetry) is dynamically local even at zero mass (a result due to Ferguson [12]). Actually, this symmetry has other interesting aspects: it is spontaneously broken in Minkowski space [29], for example, and the automorphism group of the functor A is noncompact: Aut(A )=Z 2 ⋉R[13]. 8. Summary and outlook We have shown that the notion of the ‘same physics in all spacetimes’ can be given a formal meaning (at least in part) and can be analysed in the context of the BFV framework of locally covariant theories. While local covariance in itself does not guarantee the SPASs property, the dynamically local theories do form a class of theories with SPASs; moreover, dynamical locality seems to be a natural and useful property in other contexts. Relative Cauchy evolution enters the discussion in an essential way, and seems to be the replacement of the classical action in the axiomatic setting. A key question, given our starting point, is the extent to which the SPASs condition is sufficient as well as necessary for a class of theories to represent the same physics in all spacetimes. As a class of theories that had no subtheory embeddings other than equivalences would satisfy SPASs, there is clearly scope for further work on this issue. In particular, is it possible to formulate a notion of ‘the same physics on all spacetimes’ in terms of individual theories rather than classes of theories? In closing, we remark that the categorical framework opens a completely new way of analysing quantum field theories, namely at the functorial level. It is conceivable that all structural properties of QFT should have a formulation at this level, with the instantiations of the theory in particular spacetimes taking a secondary place. Lest this be seen as a flight to abstraction, we emphasize again that this framework is currently leading to new viewpoints and concrete calculations in cosmology and elsewhere. This provides all the more reason to understand why theories based on our experience with terrestrial particle physics can be used in very different spacetime environments while preserving the same physical content. References [1] Adámek, J., Herrlich, H., Strecker, G.E.: Abstract and concrete categories: the joy of cats. Repr. Theory Appl. Categ. (17), 1–507 (2006), reprint of the 1990 original [Wiley, New York]
226 C. J. Fewster [2] Bär, C., Ginoux, N., Pfäffle, F.: Wave equations on Lorentzian manifolds and quantization. European Mathematical Society (EMS), Zürich (2007) [3] Bernal, A.N., Sánchez, M.: Globally hyperbolic spacetimes can be defined as causal instead of strongly causal. Class. Quant. Grav. 24, 745–750 (2007), grqc/0611138 [4] Brunetti, R., Fredenhagen, K.: Microlocal analysis and interacting quantum field theories: Renormalization on physical backgrounds. Comm. Math. Phys. 208(3), 623–661 (2000) [5] Brunetti, R., Fredenhagen, K., Verch, R.: The generally covariant locality principle: A new paradigm for local quantum physics. Commun. Math. Phys. 237, 31–68 (2003) [6] Brunetti, R., Ruzzi, G.: Superselection sectors and general covariance. I. Commun. Math. Phys. 270, 69–108 (2007) [7] Brunetti, R., Ruzzi, G.: Quantum charges and spacetime topology: The emergence of new superselection sectors. Comm. Math. Phys. 287(2), 523–563 (2009) [8] Dappiaggi, C., Fredenhagen, K., Pinamonti, N.: Stable cosmological models driven by a free quantum scalar field. Phys. Rev. D77, 104015 (2008) [9] Degner, A., Verch, R.: Cosmological particle creation in states of low energy. J. Math. Phys. 51(2), 022302 (2010) [10] Dikranjan, D., Tholen, W.: Categorical structure of closure operators, Mathematics and its Applications, vol. 346. Kluwer Academic Publishers Group, Dordrecht (1995) [11] Dimock, J.: Algebras of local observables on a manifold. Commun. Math. Phys. 77, 219–228 (1980) [12] Ferguson, M.: In preparation [13] Fewster, C.J.: In preparation [14] Fewster, C.J.: Quantum energy inequalities and local covariance. II. Categorical formulation. Gen. Relativity Gravitation 39(11), 1855–1890 (2007) [15] Fewster, C.J., Pfenning, M.J.: Quantum energy inequalities and local covariance. I: Globally hyperbolic spacetimes. J. Math. Phys. 47, 082303 (2006) [16] Fewster, C.J., Verch, R.: Dynamical locality; Dynamical locality for the free scalar field. In preparation [17] Fulling, S.A.: Nonuniqueness of canonical field quantization in Riemannian space-time. Phys. Rev. D7, 2850–2862 (1973) [18] Fulling, S.A., Narcowich, F.J., Wald, R.M.: Singularity structure of the twopoint function in quantum field theory in curved spacetime. II. Ann. Physics 136(2), 243–272 (1981) [19] Fulling, S.A., Ruijsenaars, S.N.M.: Temperature, periodicity and horizons. Phys. Rept. 152, 135–176 (1987) [20] Haag, R.: Local Quantum Physics: Fields, Particles, Algebras. Springer-Verlag, Berlin (1992) [21] Hawking, S.W., Ellis, G.F.R.: The Large Scale Structure of Space-Time. Cambridge University Press, London (1973) [22] Hollands, S., Wald, R.M.: Local Wick polynomials and time ordered products of quantum fields in curved spacetime. Commun. Math. Phys. 223, 289–326 (2001)
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Quantum Field Theory and Gravity Co
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Contents Preface ..................
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Preface The present volume arose fr
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Preface ix 6. (How) can we test qua
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Preface xi Felix Finster, Andreas G
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Preface xiii it is related to other
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Quantum Gravity: Whence, Whither? C
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Quantum Gravity: Whence, Whither? 3
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16 K. Fredenhagen and K. Rejzner fi
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18 K. Fredenhagen and K. Rejzner Th
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20 K. Fredenhagen and K. Rejzner 4.
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22 K. Fredenhagen and K. Rejzner 5.
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The “Big Wave” Theory for Dark
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Discrete and Continuum Third Quanti
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Unsharp Values, Domains and Topoi A
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Unsharp Values, Domains and Topoi 6
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Causal Boundary of Spacetimes: Revi
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Causal Boundaries 99 to the Gromov
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Causal Boundaries 101 I + (ρ) ρ P
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Causal Boundaries 103 Figure 2. The
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Causal Boundaries 105 more pairings
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Causal Boundaries 107 point of the
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Causal Boundaries 109 (0, 1) x n x
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Causal Boundaries 111 to Busemann f
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Causal Boundaries 113 respectively.
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Causal Boundaries 115 6.3. Structur
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Causal Boundaries 117 Qualitative F
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Causal Boundaries 119 [26] E. Mingu
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122 D. Häfner Let us give an idea
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124 D. Häfner Figure 1. The collap
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126 D. Häfner Figure 2. The manifo
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128 D. Häfner and the angular mome
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130 D. Häfner Lemma 3.5. There exi
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132 D. Häfner Proposition 4.4. The
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134 D. Häfner 6. Strategy of the p
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136 D. Häfner [3] B. Carter, Black
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138 R. Oeckl it is less compelling
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140 R. Oeckl Depending on the theor
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142 R. Oeckl 2.3. Recovery of stand
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144 R. Oeckl where the condition A
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146 R. Oeckl Before we proceed to i
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148 R. Oeckl the complex classical
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150 R. Oeckl The corresponding anni
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152 R. Oeckl Proposition 4.1 (Coher
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154 R. Oeckl much larger than the s
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156 R. Oeckl Setting F equal to F
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158 F. Finster, A. Grotz and D. Sch
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Page 189 and 190: 174 F. Finster, A. Grotz and D. Sch
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Page 233 and 234: 218 C. J. Fewster theory. The resul
Page 235 and 236: 220 C. J. Fewster Following [7], a
Page 237 and 238: 222 C. J. Fewster Sketch of proof.
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Page 244 and 245: Local Covariance, Renormalization A
Page 246 and 247: Local Thermal Equilibrium and Cosmo
Page 272 and 273: Shape Dynamics. An Introduction Jul
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Shape Dynamics. An Introduction 275
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300 M. Kiessling In the following,
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302 M. Kiessling where “δ( · )
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304 M. Kiessling the point charge,
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306 M. Kiessling (2.17) and (2.18)
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308 M. Kiessling Maxwell’s “law
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310 M. Kiessling argued that E f (
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312 M. Kiessling the Maxwell-Born-I
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314 M. Kiessling removal. For insta
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316 M. Kiessling ∂ 4πc that for
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318 M. Kiessling d dt Dirac, on the
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320 M. Kiessling The Lorenz-Lorentz
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322 M. Kiessling ( 1 c Lorentz and
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324 M. Kiessling potential fields
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326 M. Kiessling as I have done her
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328 M. Kiessling just the Hamilton-
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330 M. Kiessling 7. Closing remarks
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332 M. Kiessling [Bor1937] Born, M.
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334 M. Kiessling [Lié1898] Liénar
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How Unique Are Higher-dimensional B
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Equivalence Principle, Quantum Mech
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Atom Interferometry 347 The second
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Atom Interferometry 349 α CR , aim
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Atom Interferometry 351 of this mas
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Atom Interferometry 353 height B A
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Atom Interferometry 355 iff ψ = (
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Atom Interferometry 357 have be rea
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Atom Interferometry 359 where F (t
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Atom Interferometry 361 5.2. Interf
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Atom Interferometry 363 Evaluating
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Atom Interferometry 365 where the l
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Atom Interferometry 367 Then they s
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Atom Interferometry 369 [8] T.M. Fo
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Index n-point function, 51, 146, 23
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Index 373 conformal field theory, 1
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Index 375 gravitational redshift, 2
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Index 377 operator product, 138 par
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Index 379 standard model of particl
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