References References marked with (WZ) can also be found (in English translation if applicable) in Wheeler and Zurek 1983, those with (LR) in Leff and Rex 1990. Some <strong>of</strong> my own (p)reprints are available through www.zeh-hd.de. <strong>The</strong> page <strong>of</strong> this book on which the reference is quoted is added in square brackets. Aharonov, Y., Bergmann, P.G., and Lebowitz, J.L. (1964): <strong>Time</strong> symmetry in the quantum process <strong>of</strong> measurement. Phys. Rev. 134, B1410 – (WZ) – [131,201] Aharonov, Y., and Vaidman, L. (1991): Complete description <strong>of</strong> a quantum system at a given time. J. Phys. A24, 2315 – [126] Albrecht, A., (1992): Investigating decoherence in a simple system. Phys. Rev. D46, 5504 – [133] Albrecht, A. (1993): Following a “collapsing” wave function. Phys. Rev. D48, 3768 – [133] Alicki, R., and Lendi, K. (1987): Quantum Dynamical Semigroups and Applications (Springer) – [118] Anderson, E. (2006): Emergent semiclassical time in quantum gravity. E-print grqc/0611007 and gr-qc/0611008 – [193] Anglin, J.R., and Zurek, W.H. (1996): A precision test <strong>of</strong> decoherence. E-print quant-ph/9611049 – [110] Arndt, M., Nairz, O., Vos-Andreae, J., Keler, C., van der Zouw, G., and Zeilinger, A. (1999): Wave–particle duality <strong>of</strong> C 60 molecules. Nature 401, 680 – [104] Arnol’d, V.I., and Avez, A. (1968): Ergodic Problems <strong>of</strong> Classical Mechanics (Benjamin) – [55] Arnowitt, R., Deser, S., and Misner, C.W. (1962): <strong>The</strong> dynamics <strong>of</strong> general relativity. In: Gravitation: An Introduction to Current Research, ed. by Witten, L. (Wiley) – [161] Ashtekhar, A. (1987): New Hamiltonian formulation <strong>of</strong> general relativity. Phys. Rev. D36, 1587 – [178] Atkinson, D. (2006): Does quantum electrodynamics have an arrow <strong>of</strong> time? Stud. Hist. Phil. Mod. Phys. 37, 528 – [3]
210 References Baierlein, R.F., Sharp, D.H., and Wheeler, J.A. (1962): Three-dimensional geometry as carrier <strong>of</strong> information about time. Phys. Rev. 126, 1864 – [163] Balian, R. (1991): From Microphysics to Macrophysics (Springer) – [68] Banks, T. (1985): TCP, quantum gravity, the cosmological constant, and all that .... Nucl. Physics B249, 332 – [186,189,190] Barbour, J.B. (1986): Leibnizian time, Machian dynamics and quantum gravity. In: Quantum Concepts in Space and <strong>Time</strong>, ed. by Penrose, R., and Isham, C.J. (Clarendon Press) – [13,179] Barbour, J.B. (1989): Absolute or Relative Motion? (Cambridge University Press) – [16] Barbour, J.B. (1994b): <strong>The</strong> timelessness <strong>of</strong> quantum gravity II. <strong>The</strong> appearance <strong>of</strong> dynamics in static configurations. Class. Quantum Grav. 11, 2875 – [192] Barbour, J.B. (1999): <strong>The</strong> End <strong>of</strong> <strong>Time</strong> (Weidenfeld & Nicolson) – [13,16,165,170] Barbour, J.B., and Bertotti, B. (1982): Mach’s principle and the structure <strong>of</strong> dynamical theories. Proc. R. Soc. London A382, 295 – [165] Barbour, J.B., and Pfister, H. (Eds.) (1995): Mach’s Principle: From Newton’s Bucket to Quantum Gravity (Birkhäuser, Basel) – [13,163] Bardeen, J.M., Carter, B., and Hawking, S.W. (1973): <strong>The</strong> four laws <strong>of</strong> black hole mechanics. Comm. Math. Phys. 31, 161 – [146] Bardeen, J., Cooper, L.N., and Schrieffer, J.R. (1957): <strong>The</strong>ory <strong>of</strong> superconductivity. Phys. Rev. 108, 1175 – [151] Barrow, J.D., and Tipler, F.J. (1986): <strong>The</strong> Anthropic Cosmological Principle (Oxford University Press) – [84] Bartnik, R., and Fodor, G. (1993): On the restricted validity <strong>of</strong> the thin sandwich conjecture. Phys. Rev. D48, 3596 – [162] Barvinsky, A.O., Kamenshchik, A. Yu., Kiefer, C., and Mishakov, I.V. (1999): Decoherence in quantum cosmology at the onset <strong>of</strong> inflation. Nucl. Phys. B551, 374 – [187,191] Bekenstein, J.D. (1973): Black holes and entropy. Phys. Rev. D7, 2333 – [146] Bekenstein, J.D. (1980): Black-hole thermodynamics. Physics Today 33, 24 – [148] Belavkin, V.P. (1988): Nondemolition measurements, nonlinear filtering and dynamic programming <strong>of</strong> quantum stochastic processes. In: Modeling and Control <strong>of</strong> Systems, ed. by Blanquière, A. (Springer) – [118] Bell, J.S. (1964): On the Einstein–Podolsky–Rosen paradox. Physics 1, 195 – (WZ) – [96] Bell, J.S. (1981): Quantum mechanics for cosmologists. In: Quantum Gravity II , ed. by Isham, C.J., Penrose, R., and Sciama, D.W. (Clarendon Press) – [127] Beller, M. (1996): <strong>The</strong> conceptual and the anecdotal history <strong>of</strong> quantum mechanics. Found. Phys. 26, 545 – [125] Beller, M. (1999): Quantum Dialogue (University <strong>of</strong> Chicago Press) – [125] Bennett, C.H. (1973): Logical reversibility <strong>of</strong> computation. IBM J. Res. Dev. 17, 525 – (LR) – [74,75,76] Bennett, C.H. (1987): Demons, engines, and the second law. Sci. Amer. 257, 108 – [75,76] Bennett, C.H., and Landauer, R. (1985): <strong>The</strong> fundamental physical limits <strong>of</strong> computation. Sci. Amer. 253, 38 – [76] Bertalanffi, L. von (1953): Biophysik des Fließgleichgewichts (Vieweg) – [77] Birrell, N.D., and Davies, P.C.W. (1983): Quantum Fields in Curved Space (Cambridge University Press) – [153]
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