Stochastic quantum mechanics
Stochastic quantum mechanics (or the stochastic interpretation) is an interpretation of quantum mechanics. This interpretation is based on a reformulation of quantum mechancis in which the dynamics of all particles is governed by a stochastic differential equation. Thus, according to the stochastic interpretation, quantum particles follow well-defined random trajectories in space(time), similar to a Brownian motion.
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The modern application of stochastics to quantum mechanics involves the assumption of spacetime stochasticity, the idea that the small-scale structure of spacetime is undergoing both metric and topological fluctuations (John Archibald Wheeler's "quantum foam"), and that the averaged result of these fluctuations recreates a more conventional-looking metric at larger scales that can be described using classical physics, along with an element of nonlocality that can be described using quantum mechanics. A stochastic interpretation of quantum mechanics is due to persistent vacuum fluctuation. The main idea is that vacuum or spacetime fluctuations are the reason for quantum mechanics and not a result of it as it is usually considered.
Stochastic mechanics
The first relatively coherent stochastic theory of quantum mechanics was put forward by Hungarian physicist Imre Fényes[1] who was able to show the Schrödinger equation could be understood as a kind of diffusion equation for a Markov process.[2][3]
Louis de Broglie[4] felt compelled to incorporate a stochastic process underlying quantum mechanics to make particles switch from one pilot wave to another.[5] Perhaps the most widely known theory where quantum mechanics is assumed to describe an inherently stochastic process was put forward by Edward Nelson[6] and is called stochastic mechanics. This was also developed by Davidson, Guerra, Ruggiero, Pavon and others.[7]
Stochastic Quantization
The postulates of Stochastic Mechanics can be summarized in a stochastic quantization condition that was formulated by Nelson[8] and reformulated by Kuipers.[9] For a non-relativistic theory on this condition states:
- the trajectory of a quantum particle is described by the real projection of a complex semi-martingale: with , where is a continuous finite variation process and is a complex martingale;
- the trajectory stochastically extremizes an action ;
- the martingale is a continuous process with independent increments and finite moments. Furthermore, its quadratic variation is fixed by the structure relation where is the mass of the particle;
- the time reversed process exists and is subjected to the same dynamical laws.
Using the decomposition , and the fact that has finite variation, one immediately finds that the quadratic variation of and is given by
.
Hence, by Lévy's characterization of Brownian motion, and describe two maximally correlated Wiener processes with a drift described by the finite variation process .
The stochastic quantization procedure can be generalized, such that it describes a larger class of stochastic theories.[9] In this generalization, the structure relation is given by with The covariation of and is then given by
.
This generalized theory describes quantum mechanics for , while, for , it describes a Brownian motion with diffusion coefficient . In addition, the generalized theory is symmetric under the operation .
The term stochastic quantization to describe this quantization procedure was introduced[10] in the 1970's. Nowadays, stochastic quantization more commonly refers to a framework developed by Parisi and Wu in 1981. Consequently, the quantization procedure developed in stochastic mechanics is sometimes also referred to as Nelson's stochastic quantization or stochasticization.[11]
Velocity of the Process
The stochastic process is almost surely nowhere differentiable, such that the velocity along the process is not well-defined. However, it turns out that there exist velocity fields, defined using conditional expectations. These are given by
and are called the forward and backward Itô velocity of the process. Since the process is not differentiable, these velocities are, in general, not equal to each other. The physical interpretation of this fact is as follows: at any time the particle is subjected to a random force that instantaneously changes its velocity from to . As the two velocity fields are not equal, there is no unique notion of velocity for the process . In fact, any velocity given by
with represents a valid choice for the velocity of the process . This is particularly true for the special case denoted by , which is the Stratonovich velocity field.
Since has a non-vanishing quadratic variation, one can additionally define second order velocity fields given by
,
.
The time-reversibility postulate imposes a relation on these two fields such that . Moreover, using the structure relation by which the quadratic variation is fixed, one finds that with . It immediately follows that in the Stratonovich formulation the second order part of the velocity vanishes, i.e. .
Using the existence of the velocity fields , one can formally define the velocity processes by the Itô integral . Similarly, one can formally define a process by the Stratonovich integral and a second order velocity process by the Stieltjes integral . Using the structure relation, one then finds that the second order velocity process is given by . However, the processes and are not well-defined: the first moments exist and are given by , but the quadratic moments diverge, i.e. . The physical interpretation of this divergence is that in the position representation the position is known precisely, but the velocity has an infinite uncertainty.
Stochastic Action
The postulates of stochastic mechanics state that the stochastic trajectory must extremize a stochastic action , but they do not specify the stochastic Lagrangian . This Lagrangian can be obtained from a classical Lagrangian using a standard procedure. Here, we consider a classical Lagrangian of the form
,
where denotes the mass of the particle, the charge under the vector potential , and is a scalar potential.
An important property of this Lagrangian is the principle of gauge invariance. This can be made explicit by defining a new action through the addition of a total derivative term to the original action, such that
,
where and . Thus, since the dynamics should not be affected by the addition of a total derivative to the action, the action is gauge invariant under the above redefinition of the potentials for an arbitrary differentiable function .
In order to construct a stochastic Lagrangian corresponding to this classical Lagrangian, one must look for a minimal extension of the above Lagrangian that respects this gauge invariance.[12] In the Stratonovich formulation of the theory, this can be done straightforwardly, since the differential operator in the Stratonovich formulation is given by
.
Therefore, the Stratonovich Lagrangian can be obtained by replacing the classical velocity by the complex Stratonovich velocity , such that
In the Itô formulation, things are more complicated, as the total derivative is given by Itô's lemma: .
Due to the presence of the second order derivative term, the gauge invariance is broken. However, this can be restored by adding a derivative of the vector potential to the Lagrangian. Hence, the stochastic Lagrangian in the Itô formulation is given by
.
The stochastic action can be defined using the Stratonovich Lagrangian, which is equal to the action defined by the Itô Lagrangian up to a divergent term:[8]
.
The divergent term can be calculated[9] and is given by
,
where are winding numbers that count the winding of the path around the pole at .
As the divergent term is constant, it does not contribute to the equations of motion. For this reason, this term has been discarded in early works on stochastic mechanics.[8] However, when this term is discarded, stochastic mechanics cannot account for the appearance of discrete spectra in quantum mechanics. This issue is known as Wallstrom's criticism,[13] and can be resolved by properly taking into account the divergent term.[9]
There also exists a Hamiltonian formulation of stochastic mechanics.[14] It starts from the definition of canonical momenta:
,
.
The Hamiltonian in the Stratonovich formulation can then be obtained by the first order Legendre transform:
.
In the Itô formulation, on the other hand, the Hamiltonian is obtained through a second order Legendre transform:[15]
.
Stochastic electrodynamics
Stochastic quantum mechanics can be applied to the field of electrodynamics and is called stochastic electrodynamics (SED).[16] SED differs profoundly from quantum electrodynamics (QED) but is nevertheless able to account for some vacuum-electrodynamical effects within a fully classical framework.[17] In classical electrodynamics it is assumed there are no fields in the absence of any sources, while SED assumes that there is always a constantly fluctuating classical field due to zero-point energy. As long as the field satisfies the Maxwell equations there is no a priori inconsistency with this assumption.[18] Since Trevor W. Marshall[19] originally proposed the idea it has been of considerable interest to a small but active group of researchers.[20]
See also
References
Notes
- See I. Fényes (1946, 1952)
- Davidson (1979), p. 1
- de la Peña & Cetto (1996), p. 36
- de Broglie (1967)
- de la Peña & Cetto (1996), p. 36
- See E. Nelson (1966, 1985, 1986)
- de la Peña & Cetto (1996), p. 36
- E. Nelson (1985)
- F. Kuipers (2023)
- cf. e.g. Yasue (1979)
- Nelson (2014)
- Zambrini (1985)
- Wallstrom (1989, 1994)
- Zambrini (1985); Pavon (1995)
- Huang, Zambrini (2023)
- de la Peña & Cetto (1996), p. 65
- Milonni (1994), p. 128
- Milonni (1994), p. 290
- See T. W. Marshall (1963, 1965)
- Milonni (1994), p. 129
Papers
- de Broglie, L. (1967). "Le Mouvement Brownien d'une Particule Dans Son Onde". C. R. Acad. Sci. B264: 1041.
- Davidson, M. P. (1979). "The Origin of the Algebra of Quantum Operators in the Stochastic Formulation of Quantum Mechanics". Letters in Mathematical Physics. 3 (5): 367–376. arXiv:quant-ph/0112099. Bibcode:1979LMaPh...3..367D. doi:10.1007/BF00397209. ISSN 0377-9017. S2CID 6416365.
- Fényes, I. (1946). "A Deduction of Schrödinger Equation". Acta Bolyaiana. 1 (5): ch. 2.
- Fényes, I. (1952). "Eine wahrscheinlichkeitstheoretische Begründung und Interpretation der Quantenmechanik". Zeitschrift für Physik. 132 (1): 81–106. Bibcode:1952ZPhy..132...81F. doi:10.1007/BF01338578. ISSN 1434-6001. S2CID 119581427.
- Guerra, F. (1981). "Structural aspects of stochastic mechanics and stochastic field theory". Physical Reports. 77 (3): 263–312. Bibcode:1981PhR....77..263G. doi:10.1016/0370-1573(81)90078-8.
- Kuipers, F. (2023). "Quantum mechanics from stochastic processes". European Physical Journal Plus. 138 (6): 542. arXiv:2304.07524. Bibcode:2023EPJP..138..542K. doi:10.1140/epjp/s13360-023-04184-x. S2CID 258180197.
- Lindgren, J.; Liukkonen, J. (2019). "Quantum Mechanics can be understood through stochastic optimization on spacetimes". Scientific Reports. 9 (1): 19984. Bibcode:2019NatSR...919984L. doi:10.1038/s41598-019-56357-3. PMC 6934697. PMID 31882809.
- Marshall, T. W. (1963). "Random Electrodynamics". Proceedings of the Royal Society A: Mathematical, Physical and Engineering Sciences. 276 (1367): 475–491. Bibcode:1963RSPSA.276..475M. doi:10.1098/rspa.1963.0220. ISSN 1364-5021. S2CID 202575160.
- Marshall, T. W. (1965). "Statistical Electrodynamics". Mathematical Proceedings of the Cambridge Philosophical Society. 61 (2): 537–546. Bibcode:1965PCPS...61..537M. doi:10.1017/S0305004100004114. ISSN 0305-0041. S2CID 251093523.
- Nelson, E. (1966). "Derivation of the Schrödinger equation from Newtonian Mechanics". Physical Review. 150 (4): 1079–1085. Bibcode:1966PhRv..150.1079N. doi:10.1103/PhysRev.150.1079.
- Nelson, E. (1986). "Field Theory and the Future of Stochastic Mechanics". In Albeverio, S.; Casati, G.; Merlini, D. (eds.). Stochastic Processes in Classical and Quantum Systems. Lecture Notes in Physics. Vol. 262. Berlin: Springer-Verlag. pp. 438–469. doi:10.1007/3-540-17166-5. ISBN 978-3-662-13589-1. OCLC 864657129.
- Nelson, E. (2014). "Stochastic mechanics of relativistic fields". Journal of Physics: Conference Series. 504 (1): 012013. Bibcode:2014JPhCS.504a2013N. doi:10.1088/1742-6596/504/1/012013. S2CID 123706792.
- Pavon, M. (1995). "A new formulation of stochastic mechanics". Physics Letters A. 209 (3–4): 143–149. Bibcode:1995PhLA..209..143P. doi:10.1016/0375-9601(95)00847-4.
- Wallstrom, T.C. (1989). "On the derivation of the Schrödinger equation from Stochastic Mechanics". Foundations of Physics Letters. 2: 113–126. doi:10.1007/BF00696108.
- Wallstrom, T.C. (1994). "Inequivalence between the Schrödinger equation and the Madelung hydrodynamic equations". Physical Review A. 49 (3): 1613–1617. doi:10.1103/PhysRevA.49.1613.
- Yasue, K. (1979). "Stochastic quantization: a review". International Journal of Theoretical Physics. 18 (12): 861–913. Bibcode:1979IJTP...18..861Y. doi:10.1007/BF00669566. S2CID 120858652.
- Zambrini, J.C. (1985). "Stochastic dynamics: a review of stochastic calculus of variations". International Journal of Theoretical Physics. 24 (3): 277–327. Bibcode:1985IJTP...24..277Z. doi:10.1007/BF00669792. S2CID 122076991.
- Huang, Q.; Zambrini, J.C. (2023). "From Second-Order Differential Geometry to Stochastic Geometric Mechanics". Journal of Nonlinear Science. 33 (67): 1–127. doi:10.1007/s00332-023-09917-x.
Books
- Jammer, M. (1974). The Philosophy of Quantum Mechanics: The Interpretations of Quantum Mechanics in Historical Perspective. New York: Wiley. ISBN 0-471-43958-4. LCCN 74013030. OCLC 613797751.
- Kuipers, F. (2023). Stochastic Mechanics: the unification of quantum mechanics with Brownian motion. SpringerBriefs in Physics. Cham: SpringerBriefs in Physics. arXiv:2301.05467. doi:10.1007/978-3-031-31448-3. ISBN 978-3-031-31447-6. S2CID 255825676.
- Milonni, Peter W. (1994). The Quantum Vacuum: An Introduction to Quantum Electrodynamics. Boston: Academic Press. ISBN 0-12-498080-5. LCCN 93029780. OCLC 422797902.
- Namsrai, K. (1985). Nonlocal Quantum Field Theory and Stochastic Quantum Mechanics. Dordrecht; Boston: D. Reidel Publishing Co. doi:10.1007/978-94-009-4518-0. ISBN 90-277-2001-0. LCCN 85025617. OCLC 12809936.
- Nelson, E. (1966). Dynamical Theories of Brownian Motion. Princeton: Princeton University Press. ISBN 9780691079509. OCLC 25799122.
- Nelson, E. (1985). Quantum Fluctuations. Princeton: Princeton University Press. ISBN 0-691-08378-9. LCCN 84026449. OCLC 11549759.
- de la Peña, Luis; Cetto, Ana María (1996). van der Merwe, Alwyn (ed.). The Quantum Dice: An Introduction to Stochastic Electrodynamics. Dordrecht; Boston; London: Kluwer Academic Publishers. ISBN 0-7923-3818-9. LCCN 95040168. OCLC 832537438.