Arkady Plotnitsky The Principles of Quantum Theory, From Planck's Quanta to the Higgs Boson The Nature of Quantum Reality and the Spirit of Copenhagen The Principles of Quantum Theory, From Planck’s Quanta to the Higgs Boson Arkady Plotnitsky The Principles of Quantum Theory, From Planck’s Quanta to the Higgs Boson The Nature of Quantum Reality and the Spirit of Copenhagen Arkady Plotnitsky Theory and Cultural Studies Program Purdue University West Lafayette, IN, USA ISBN 978-3-319-32066-3 ISBN 978-3-319-32068-7 (eBook) DOI 10.1007/978-3-319-32068-7 Library of Congress Control Number: 2016940380 © Springer International Publishing Switzerland 2016 This work is subject to copyright. 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Neither the publisher nor the authors or the editors give a warranty, express or implied, with respect to the material contained herein or for any errors or omissions that may have been made. Printed on acid-free paper This Springer imprint is published by Springer Nature The registered company is Springer International Publishing AG Switzerland I am working out a quantum theory about it for it is really most tantalizing state of affairs. —James Joyce, Finnegans Wake (Joyce 2012, p. 149) Preface I would like to begin with the endpoint of the history to be traversed by this study, the discovery of the Higgs boson, arguably the greatest event of fundamental phys- ics in the twenty-first century thus far, and, thus far, a culminating event in the his- tory of quantum physics. This discovery has been discussed at all levels and in all media, with photographs of the “events” testifying to the existence of the Higgs boson and of various components, staggering in their complexity, of the Large Hadron Collider (LHC), and the relevant parts of the mathematical formalism of quantum field theory (e.g., “The Higgs Boson,” Wikipedia; CERN: Accelerated Science: Images). These pictures are well known and easily located on the Web. I only cite the key part of the formalism, the epistemological nature of which will be discussed in Chap. 6: In the Standard Model, the Higgs field is a four component scalar field that forms a complex doublet of the weak isospin SU(2) symmetry: 1 æf1+if2ö f= ç ÷ 2 èf0 +if3ø while the field had charge +1/2 under the weak hypercharge U(1) symmetry (in the conven- tion where the electric charge, Q, the weak isospin, I, and the weak hypercharge, Y, are 3 related by Q = I + Y). 3 The Higgs part of the Lagrangian is 2  =æç¶ -igWata-ig¢B ö÷ +m2f†f–l(f†f)2, H è m m 2 mø where Wμα and Bμ are the gauge bosons of the SU(2) and U(1) symmetries, and g and g′ their respective coupling constant, ta =sa/2 (where σα are the Pauli matrices) a complete set of generators of the SU(2) symmetry, and l>0 andm2>0, so that the ground state breaks the SU(2) symmetry. The ground state of the Higgs field (the bottom of the potential) vii viii Preface is degenerate with different ground states related to each other by an SU(2) gauge transfor- mation. It is always possible to pick up a gauge such that the ground state f1 =f2 =f3 =0. The expectation value of ϕ0 in the ground state (the vacuum expectation value or vev) is v m 246GeV then f0 = , where v= . The measured value of this parameter is ~ . Ö2 Öl c2 It has units of mass, and is the only free parameter of the Standard Model that is not a dimensionless number. Quadratic terms W and B arise, which give masses to the W and Z μ μ bosons: v g M = W 2 g2 +g¢2 M = Z 2 M g with their ration determining the Weinberg angle, cosq = W = , and leave a massless U(1) photon, γ. W MZ g2 +g¢2 (“The Higgs Boson,” Wikipedia; Peskin and Schroeder 1995, pp. 690–700) Now, what does all this (the photographs of the corresponding events, computer generated images and data, staggering machinery of the LHC, and the mathematics just described) mean? And how is it possible? Without attempting to definitively answer these questions, this study will consider a particular perspective on them, indeed a particular way of asking them, and will suggest partial answers that arise if one adopts this perspective. This perspective is guided by understanding the nature of quantum reality, or the quantum reality of nature, and of quantum theory, from quantum mechanics to quantum field theory, in “the spirit of Copenhagen [Kopenhagener Geist der Quantenheorie],” in Heisenberg’s memorable phrase, the spirit that guides this study, as indicated by its subtitle (Heisenberg 1930, p. iv). This understanding relates nature and spirit (a relation that we seem unable to do without even when a materialist view of the world is adopted) in a new way. The spirit of Copenhagen, I argue, is defined by three great divorces from the preceding under- standing of these relationships between nature and spirit, or, to use a less theologi- cally charged expression, nature and mind (technically, German Geist means both), specifically scientific thought in modern physics: reality from realism, probability from causality, and locality from relativity. It is true that the last of these divorces did not shape the rise of the spirit of Copenhagen in the way the first two did, but it became a major part of this spirit nevertheless. I shall comment on these three “divorces” and define the corresponding concepts below, and discuss them in detail in Chap. 1 and elsewhere in this study. For the moment, the spirit of Copenhagen has its history in the preceding understanding of nature and mind, and their relationships. This history extends even as far as the pre- Socratics, and I shall address some of these more distant historical connections later in this study. However, the most significant historical trajectory of this study prior to the birth of quantum theory, inaugurated by Planck’s discovery of the quantum of action, h, begins with scientific modernity. There is no modernity other than Preface ix scientific, because modernity is defined, partially but decisively, by the rise of mod- ern, mathematical-experimental, sciences of nature. Consider John Milton’s description of chaos in Paradise Lost. This description and Milton’s poem itself were written in the aftermath of the rise of mathematical- experimental science, at that stage physics and astronomy, with Copernicus, Kepler, and Galileo; and the poem was a response to a different world that emerged with and because of this rise, a world to which we now refer as the world of modernity. Milton’s stated aim in writing the poem is “to justify the ways of God to man,” with “justify” referring to both the nature and the justness of these ways (Milton 2004, p. 3, Paradise Lost, Book I, ll. 25–26). But why would one have needed such a book? Don’t we already have the Bible that should do so? Well, not exactly, or rather the Bible, Milton realized, was no longer sufficient to do so. As is clear from Milton’s references in Paradise Lost to post-Copernican astronomy, and Galileo’s and Boyle’s physics, Milton acutely realized that the world he lived in, the world of modernity, was defined by, in Galileo’s words, “new mathematical sciences of nature,” which brought mathematics and experiment together (Galilei 1991). “Modern science,” M. Heidegger says, “is experimental because of its mathematical project” (Heidegger 1967, p. 93). The world, as envisioned by Milton, was post- Copernican and post-Galilean. R. Boyle has already conducted his famous experi- ments on the properties of air and the existence of the vacuum, and Newton, Milton’s equally famous fellow Cambridge graduate, was soon to appear on this stage and to shape the thinking of modernity even more decisively. (Both Boyle and Newton had major alchemical and theological interests, and left voluminous writings on these subjects.) It was no longer the world of the Bible, and Milton reread or re- envisioned the Bible as consistent with this new world. For Milton, God created the world as understood by modern science and (they are, again, inseparable) scientific moder- nity. This world called for a new justification of the ways of God to man, assuming that this justification is possible, given that this new world compelled some to deny this possibility, or the existence of God in the first place. The question of this justi- fication or its possibility, which is still with us, is well outside the scope of this study. But Milton’s argument for the extraordinary complexity of this world, which, however it came about, requires the utmost reach of and may ultimately be beyond human thought, is relevant to this project. This complexity and this relevance are shown, for example and in particular, by Milton’s description of chaos in the poem: Before their eyes in sudden view appear The secrets of the hoary Deep—a dark Illimitable Ocean without bound, Without dimension: where length, breadth, and height, And time, and place, are lost; where eldest Night And Chaos, ancestors of Nature, hold Eternal anarchy, amidst the noise Of endless wars, and by confusion stand. For Hot, Cold, Moist, and Dry, four champions fierce, Strive here for maistrie, and to battle bring Their embryon atoms: they around the flag Of each his faction, in their several clans, Light-armed or heavy, sharp, smooth, swift or slow, x Preface Swarm populous, unnumbered as the sands Of Barca or Cyrene’s torrid soil, Levied to side with warring winds, and poise Their lighter wings. To whom these most adhere, He rules a moment: Chaos umpire sits, And by decision more embroils the fray By which he reigns: next him, high arbiter, Chance governs all. Into this wild Abyss, The womb of Nature, and perhaps her grave, Of neither Sea, nor Shore, not Air, nor Fire, But all these in their pregnant causes mixed Confus’dly, and which thus must ever fight, Unless th’ Almighty Maker them ordain His dark materials to create more worlds— (Milton 2004, p. 20, Paradise Lost, Book II, 890–916) The physical universe in this view is, thus, chaos, unless order emerges from it, and this happens continuously, too, even if, generally, without giving this order sta- bility. Milton’s description is presciently close to the understanding of the ultimate constitution of nature arising from quantum theory, arguably more so than Lucretius’s atomism in De Rerum Natura (Lucretius 2009), commonly claimed to be the main precursor of modern atomic theory (along with Leucippus and Democritus, and then Epicurus, on whose ideas Lucretius relies) and one of Milton’s sources. Boyle’s experiments were undoubtedly on Milton’s mind as well. Milton’s conception does not quite reach the radical form of this understanding to be advocated in this book. Both randomness and chance, and the birth and disappearance of “particles” in chaos, and thus unstable, fleeting nature of any order that might emerge in and from it (unless some power manages to be stabilized and built on this order), are all part of this book’s view of nature at the ultimate (quantum) level of its constitution. The second aspect just mentioned is specifically found in high-energy regimes and reflects or is reflected in the concept of virtual particle formation in quantum field theory, according to which the unstable, fleeting forms of order emerge from and disappear back into the foaming bubbling of chaos. This is what J. A. Wheeler refers to as “quantum foam” (Wheeler and Ford 2000, pp. 245–263). However, according to this study’s view, the ultimate character of this constitution, of Milton’s “embryon atoms,” which we now refer to as “elementary particles” (still an unsettled concept in fundamental physics, as is its companion concept, that of quantum field), is “dark” beyond the reach of our understanding or possibly even any conception we can form. This view is closer to, but still ultimately transcends, the ancient Greek sense of chaos as areton or alogon, as that which is beyond all comprehension, than to Milton’s conception of chaos here. On the other hand, Milton does appear to imply that our ways of experiencing the world and conceptions we could form of it, such as space, time, and causality (Kant’s three great a priori givens of our thought), are “lost,” that is, no longer applicable to chaos. Milton was certainly aware of the ancient Greek’s idea of chaos as areton or alogon. So perhaps he was closer to the argument of this book on this point, except for the ultimately theological nature of his thinking. This book is concerned with the u nrepresentable and possibly unthink- Preface xi able “dark materials” of nature as they appear in quantum physics, placed outside or even assumed to be incompatible with theology. I prefer to leave theology to Milton. If anything, this study’s understanding of the physical world, also because our inter- action with it is governed by probabilistic thinking, is closer to the world of Shakespeare’s plays (often invoked by Wheeler [e.g., Wheeler 1983, p. 204]), which tend to put the theological aside. They leave it to us “to take arms against a sea of troubles,” a sea, a place governed by chance and probability (Shakespeare 2005, p. 700, Hamlet, III.2.55-87). The sea is often invoked by Shakespeare as such a place, and Wheeler’s reference just mentioned is The Tempest (Shakespeare 2005, p. 1238, Act IV.1, 148–158). As Nestor says in Troilus and Cressida: … In the reproof of chance Lies the true proof of men. The sea being smooth, How many shallow bauble-boats dare sail Upon her patient breast, making their way With those of nobler bulk! But let the ruffian Boreas once enrage The gentle Thetis, and anon behold The strong-ribbed bark through liquid mountains cut, Bounding between the two most elements Like Perseus’s horse. Where’s then the saucy boat Whose weak untimbered sides but even now Co-rivalled greatness? Either to harbor fled, Or made a toast for Neptune. Even so Doth valor’s show and valor’s worth divide In storms of fortune. For in her ray and brightness The herd has more annoyance by the breeze Than by the tiger; but when the splitting wind Makes flexible the knees of knotted oaks, And flies fled under shade, why, then the thing of courage, As rous’d with rage, with rage does sympathize, And with an accent tun’d in selfsame key Retorts to chiding fortune. (Shakespeare 2005, p. 749, Act I.iii.33–54). Shakespeare’s music is the music of the sea, the music of chance and its complex harmonies, mixing chaos and order—chaosmic harmonies, as they were called by James Joyce, from whose Finnegans Wake M. Gell-Mann famously borrowed the term “quark” (Joyce 2012, p. 118). These chaosmic harmonies are opposed to the music of the spheres, that of Pythagoras or that of Kepler, another contemporary of Shakespeare. As my epigraph suggests, however, Joyce’s masterpiece was in turn influenced by quantum theory, not inconceivably by the discovery of antimatter, which was widely discussed at the time, just as the Higgs boson or black holes are now, and was known to Joyce (Joyce 2012, pp. 383, 149). In Joyce’s novel words transform into each other just as particles do in high-energy quantum physics. The appearance of Thetis in Shakespeare’s passage is not by chance, and she is mentioned, again, in the play: Thetis is the mother of Achilles, the greatest of heroes. It is the rage of Achilles and his concern for the lack of virtue where The Iliad of Homer begins. While the chance to kill Achilles is small, it is bound to happen at some point