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Schrödinger–Newton equation

April 11, 2024

The Schrödinger–Newton equation, sometimes referred to as the Newton–Schrödinger or Schrödinger–Poisson equation, is a nonlinear modification of the Schrödinger equation with a Newtonian gravitational potential, where the gravitational potential emerges from the treatment of the wave function as a mass density, including a term that represents interaction of a particle with its own gravitational field. The inclusion of a self-interaction term represents a fundamental alteration of quantum mechanics.[1] It can be written either as a single integro-differential equation or as a coupled system of a Schrödinger and a Poisson equation. In the latter case it is also referred to in the plural form.

The Schrödinger–Newton equation was first considered by Ruffini and Bonazzola[2] in connection with self-gravitating boson stars. In this context of classical general relativity it appears as the non-relativistic limit of either the Klein–Gordon equation or the Dirac equation in a curved space-time together with the Einstein field equations.[3] The equation also describes fuzzy dark matter and approximates classical cold dark matter described by the Vlasov–Poisson equation in the limit that the particle mass is large.[4]

Later on it was proposed as a model to explain the quantum wave function collapse by Lajos Diósi[5] and Roger Penrose,[6][7][8] from whom the name "Schrödinger–Newton equation" originates. In this context, matter has quantum properties, while gravity remains classical even at the fundamental level. The Schrödinger–Newton equation was therefore also suggested as a way to test the necessity of quantum gravity.[9]

In a third context, the Schrödinger–Newton equation appears as a Hartree approximation for the mutual gravitational interaction in a system of a large number of particles. In this context, a corresponding equation for the electromagnetic Coulomb interaction was suggested by Philippe Choquard at the 1976 Symposium on Coulomb Systems in Lausanne to describe one-component plasmas. Elliott H. Lieb provided the proof for the existence and uniqueness of a stationary ground state and referred to the equation as the Choquard equation.[10]

Overview edit

As a coupled system, the Schrödinger–Newton equations are the usual Schrödinger equation with a self-interaction gravitational potential

 
where  V  is an ordinary potential, and the gravitational potential   representing the interaction of the particle with its own gravitational field, satisfies the Poisson equation
 
Because of the back coupling of the wave-function into the potential, it is a nonlinear system.

Replacing   with the solution to the Poisson equation produces the integro-differential form of the Schrödinger–Newton equation:

 
It is obtained from the above system of equations by integration of the Poisson equation under the assumption that the potential must vanish at infinity.

Mathematically, the Schrödinger–Newton equation is a special case of the Hartree equation for n = 2 . The equation retains most of the properties of the linear Schrödinger equation. In particular, it is invariant under constant phase shifts, leading to conservation of probability and exhibits full Galilei invariance. In addition to these symmetries, a simultaneous transformation

 
maps solutions of the Schrödinger–Newton equation to solutions.[11][12] The stationary equation, which can be obtained in the usual manner via a separation of variables, possesses an infinite family of normalisable solutions of which only the stationary ground state is stable.[13][14][15]

Relation to semi-classical and quantum gravity edit

The Schrödinger–Newton equation can be derived under the assumption that gravity remains classical, even at the fundamental level, and that the right way to couple quantum matter to gravity is by means of the semiclassical Einstein equations. In this case, a Newtonian gravitational potential term is added to the Schrödinger equation, where the source of this gravitational potential is the expectation value of the mass density operator or mass flux-current.[16] In this regard, if gravity is fundamentally classical, the Schrödinger–Newton equation is a fundamental one-particle equation, which can be generalised to the case of many particles (see below).

If, on the other hand, the gravitational field is quantised, the fundamental Schrödinger equation remains linear. The Schrödinger–Newton equation is then only valid as an approximation for the gravitational interaction in systems of a large number of particles and has no effect on the centre of mass.[17]

Many-body equation and centre-of-mass motion edit

If the Schrödinger–Newton equation is considered as a fundamental equation, there is a corresponding N-body equation that was already given by Diósi[5] and can be derived from semiclassical gravity in the same way as the one-particle equation:

 
The potential   contains all the mutual linear interactions, e.g. electrodynamical Coulomb interactions, while the gravitational-potential term is based on the assumption that all particles perceive the same gravitational potential generated by all the marginal distributions for all the particles together.

In a Born–Oppenheimer-like approximation, this N-particle equation can be separated into two equations, one describing the relative motion, the other providing the dynamics of the centre-of-mass wave-function. For the relative motion, the gravitational interaction does not play a role, since it is usually weak compared to the other interactions represented by  . But it has a significant influence on the centre-of-mass motion. While   only depends on relative coordinates and therefore does not contribute to the centre-of-mass dynamics at all, the nonlinear Schrödinger–Newton interaction does contribute. In the aforementioned approximation, the centre-of-mass wave-function satisfies the following nonlinear Schrödinger equation:

 
where M is the total mass, R is the relative coordinate,   the centre-of-mass wave-function, and   is the mass density of the many-body system (e.g. a molecule or a rock) relative to its centre of mass.[18]

In the limiting case of a wide wave-function, i.e. where the width of the centre-of-mass distribution is large compared to the size of the considered object, the centre-of-mass motion is approximated well by the Schrödinger–Newton equation for a single particle. The opposite case of a narrow wave-function can be approximated by a harmonic-oscillator potential, where the Schrödinger–Newton dynamics leads to a rotation in phase space.[19]

In the context where the Schrödinger–Newton equation appears as a Hartree approximation, the situation is different. In this case the full N-particle wave-function is considered a product state of N single-particle wave-functions, where each of those factors obeys the Schrödinger–Newton equation. The dynamics of the centre-of-mass, however, remain strictly linear in this picture. This is true in general: nonlinear Hartree equations never have an influence on the centre of mass.

Significance of effects edit

A rough order-of-magnitude estimate of the regime where effects of the Schrödinger–Newton equation become relevant can be obtained by a rather simple reasoning.[9] For a spherically symmetric Gaussian,

 
the free linear Schrödinger equation has the solution
 
The peak of the radial probability density   can be found at
 
Now we set the acceleration
 
of this peak probability equal to the acceleration due to Newtonian gravity:
 
using that   at time  . This yields the relation
 
which allows us to determine a critical width for a given mass value and conversely. We also recognise the scaling law mentioned above. Numerical simulations[12][1] show that this equation gives a rather good estimate of the mass regime above which effects of the Schrödinger–Newton equation become significant.

For an atom the critical width is around 1022 metres, while it is already down to 10−31 metres for a mass of one microgram. The regime where the mass is around 1010 atomic mass units while the width is of the order of micrometers is expected to allow an experimental test of the Schrödinger–Newton equation in the future. A possible candidate are interferometry experiments with heavy molecules, which currently reach masses up to 10000 atomic mass units.

Quantum wave function collapse edit

The idea that gravity causes (or somehow influences) the wavefunction collapse dates back to the 1960s and was originally proposed by Károlyházy.[20] The Schrödinger–Newton equation was proposed in this context by Diósi.[5] There the equation provides an estimation for the "line of demarcation" between microscopic (quantum) and macroscopic (classical) objects. The stationary ground state has a width of

 
For a well-localised homogeneous sphere, i.e. a sphere with a centre-of-mass wave-function that is narrow compared to the radius of the sphere, Diósi finds as an estimate for the width of the ground-state centre-of-mass wave-function
 
Assuming a usual density around 1000 kg/m3, a critical radius can be calculated for which  . This critical radius is around a tenth of a micrometer.

Roger Penrose proposed that the Schrödinger–Newton equation mathematically describes the basis states involved in a gravitationally induced wavefunction collapse scheme.[6][7][8] Penrose suggests that a superposition of two or more quantum states having a significant amount of mass displacement ought to be unstable and reduce to one of the states within a finite time. He hypothesises that there exists a "preferred" set of states that could collapse no further, specifically, the stationary states of the Schrödinger–Newton equation. A macroscopic system can therefore never be in a spatial superposition, since the nonlinear gravitational self-interaction immediately leads to a collapse to a stationary state of the Schrödinger–Newton equation. According to Penrose's idea, when a quantum particle is measured, there is an interplay of this nonlinear collapse and environmental decoherence. The gravitational interaction leads to the reduction of the environment to one distinct state, and decoherence leads to the localisation of the particle, e.g. as a dot on a screen.

Problems and open matters edit

Three major problems occur with this interpretation of the Schrödinger–Newton equation as the cause of the wave-function collapse:

  1. Excessive residual probability far from the collapse point
  2. Lack of any apparent reason for the Born rule
  3. Promotion of the previously strictly hypothetical wave function to an observable (real) quantity.

First, numerical studies[12][15][1] agreeingly find that when a wave packet "collapses" to a stationary solution, a small portion of it seems to run away to infinity. This would mean that even a completely collapsed quantum system still can be found at a distant location. Since the solutions of the linear Schrödinger equation tend towards infinity even faster, this only indicates that the Schrödinger–Newton equation alone is not sufficient to explain the wave-function collapse. If the environment is taken into account, this effect might disappear and therefore not be present in the scenario described by Penrose.

A second problem, also arising in Penrose's proposal, is the origin of the Born rule: To solve the measurement problem, a mere explanation of why a wave-function collapses – e.g., to a dot on a screen – is not enough. A good model for the collapse process also has to explain why the dot appears on different positions of the screen, with probabilities that are determined by the squared absolute-value of the wave-function. It might be possible that a model based on Penrose's idea could provide such an explanation, but there is as yet no known reason that Born's rule would naturally arise from it.

Thirdly, since the gravitational potential is linked to the wave-function in the picture of the Schrödinger–Newton equation, the wave-function must be interpreted as a real object. Therefore, at least in principle, it becomes a measurable quantity. Making use of the nonlocal nature of entangled quantum systems, this could be used to send signals faster than light, which is generally thought to be in contradiction with causality. It is, however, not clear whether this problem can be resolved by applying the right collapse prescription, yet to be found, consistently to the full quantum system. Also, since gravity is such a weak interaction, it is not clear that such an experiment can be actually performed within the parameters given in our universe (see the referenced discussion[21] about a similar thought experiment proposed by Eppley & Hannah[22]).

See also edit

References edit

  1. ^ a b c van Meter, J. R. (2011), "Schrödinger–Newton 'collapse' of the wave function", Classical and Quantum Gravity, 28 (21): 215013, arXiv:1105.1579, Bibcode:2011CQGra..28u5013V, CiteSeerX 10.1.1.768.3363, doi:10.1088/0264-9381/28/21/215013, S2CID 119294473
  2. ^ Ruffini, Remo; Bonazzola, Silvano (1969), "Systems of Self-Gravitating Particles in General Relativity and the Concept of an Equation of State", Physical Review, 187 (5): 1767–1783, Bibcode:1969PhRv..187.1767R, doi:10.1103/PhysRev.187.1767, hdl:2060/19690028071
  3. ^ Giulini, Domenico; Großardt, André (2012), "The Schrödinger–Newton equation as a non-relativistic limit of self-gravitating Klein–Gordon and Dirac fields", Classical and Quantum Gravity, 29 (21): 215010, arXiv:1206.4250, Bibcode:2012CQGra..29u5010G, doi:10.1088/0264-9381/29/21/215010, S2CID 118837903
  4. ^ Mocz, Philip; Lancaster, Lachlan; Fialkov, Anastasia; Becerra, Fernando; Chavanis, Pierre-Henri (2018). "Schrödinger-Poisson–Vlasov-Poisson correspondence". Physical Review D. 97 (8): 083519. arXiv:1801.03507. Bibcode:2018PhRvD..97h3519M. doi:10.1103/PhysRevD.97.083519. ISSN 2470-0010. S2CID 53956984.
  5. ^ a b c Diósi, Lajos (1984), "Gravitation and quantum-mechanical localization of macro-objects", Physics Letters A, 105 (4–5): 199–202, arXiv:1412.0201, Bibcode:1984PhLA..105..199D, doi:10.1016/0375-9601(84)90397-9, S2CID 117957630
  6. ^ a b Penrose, Roger (1996), "On Gravity's Role in Quantum State Reduction", General Relativity and Gravitation, 28 (5): 581–600, Bibcode:1996GReGr..28..581P, CiteSeerX 10.1.1.468.2731, doi:10.1007/BF02105068, S2CID 44038399
  7. ^ a b Penrose, Roger (1998), "Quantum computation, entanglement and state reduction", Philosophical Transactions of the Royal Society of London. Series A: Mathematical, Physical and Engineering Sciences, 356 (1743): 1927–1939, Bibcode:1998RSPTA.356.1927P, doi:10.1098/rsta.1998.0256, S2CID 83378847
  8. ^ a b Penrose, Roger (2014), "On the Gravitization of Quantum Mechanics 1: Quantum State Reduction", Foundations of Physics, 44 (5): 557–575, Bibcode:2014FoPh...44..557P, doi:10.1007/s10701-013-9770-0
  9. ^ a b Carlip, S. (2008), "Is quantum gravity necessary?", Classical and Quantum Gravity, 25 (15): 154010, arXiv:0803.3456, Bibcode:2008CQGra..25o4010C, doi:10.1088/0264-9381/25/15/154010, S2CID 15147227
  10. ^ Lieb, Elliott H. (1977), "Existence and uniqueness of the Minimizing Solution of Choquard's Nonlinear Equation", Studies in Applied Mathematics, 57 (2): 93–105, Bibcode:1977StAM...57...93L, doi:10.1002/sapm197757293
  11. ^ Robertshaw, Oliver; Tod, Paul (2006). "Lie point symmetries and an approximate solution for the Schrödinger–Newton equations". Nonlinearity. 19 (7): 1507–1514. arXiv:math-ph/0509066. Bibcode:2006Nonli..19.1507R. doi:10.1088/0951-7715/19/7/002. S2CID 119698934.
  12. ^ a b c Giulini, Domenico; Großardt, André (2011). "Gravitationally induced inhibitions of dispersion according to the Schrödinger–Newton Equation". Classical and Quantum Gravity. 28 (19): 195026. arXiv:1105.1921. Bibcode:2011CQGra..28s5026G. doi:10.1088/0264-9381/28/19/195026. S2CID 117102725.
  13. ^ Moroz, Irene M.; Penrose, Roger; Tod, Paul (1998). "Spherically-symmetric solutions of the Schrödinger–Newton equations". Classical and Quantum Gravity. 15 (9): 2733–2742. Bibcode:1998CQGra..15.2733M. doi:10.1088/0264-9381/15/9/019. S2CID 250885770.
  14. ^ Tod, Paul; Moroz, Irene M. (1999). "An analytical approach to the Schrödinger–Newton equations". Nonlinearity. 12 (2): 201–216. Bibcode:1999Nonli..12..201T. doi:10.1088/0951-7715/12/2/002. S2CID 250800585.
  15. ^ a b Harrison, R.; Moroz, I.; Tod, K.P. (2003). "A numerical study of the Schrödinger–Newton equations". Nonlinearity. 16 (1): 101–122. arXiv:math-ph/0208045. Bibcode:2003Nonli..16..101H. doi:10.1088/0951-7715/16/1/307. S2CID 250804091. (part 1) and (part 2).
  16. ^ Jones, K.R.W. (1995). "Newtonian quantum gravity". Australian Journal of Physics. 48 (6): 1055–1082. arXiv:quant-ph/9507001. Bibcode:1995AuJPh..48.1055J. doi:10.1071/PH951055. S2CID 119408867.
  17. ^ Bahrami, Mohammad; Großardt, André; Donadi, Sandro; Bassi, Angelo (2014). "The Schrödinger–Newton equation and its foundations". New Journal of Physics. 16 (2014): 115007. arXiv:1407.4370. Bibcode:2014NJPh...16k5007B. doi:10.1088/1367-2630/16/11/115007. S2CID 4860144.
  18. ^ Giulini, Domenico; Großardt, André (2014), "Centre-of-mass motion in multi-particle Schrödinger–Newton dynamics", New Journal of Physics, 16 (7): 075005, arXiv:1404.0624, Bibcode:2014NJPh...16g5005G, doi:10.1088/1367-2630/16/7/075005, S2CID 119144766
  19. ^ Yang, Huan; Miao, Haixing; Lee, Da-Shin; Helou, Bassam; Chen, Yanbei (2013), "Macroscopic Quantum Mechanics in a Classical Spacetime", Physical Review Letters, 110 (17): 170401, arXiv:1210.0457, Bibcode:2013PhRvL.110q0401Y, doi:10.1103/PhysRevLett.110.170401, PMID 23679686, S2CID 34063658
  20. ^ Károlyházy, F. (1966), "Gravitation and Quantum Mechanics of Macroscopic Objects", Il Nuovo Cimento A, 42 (2): 390–402, Bibcode:1966NCimA..42..390K, doi:10.1007/BF02717926, S2CID 124429072
  21. ^ Mattingly, James (2006). "Why Eppley and Hannah's thought experiment fails". Physical Review D. 73 (6): 064025. arXiv:gr-qc/0601127. Bibcode:2006PhRvD..73f4025M. doi:10.1103/physrevd.73.064025. S2CID 12485472.
  22. ^ Eppley, Kenneth; Hannah, Eric (1977), "The necessity of quantizing the gravitational field", Foundations of Physics, 7 (1–2): 51–68, Bibcode:1977FoPh....7...51E, doi:10.1007/BF00715241, S2CID 123251640

April 11, 2024
schrödinger, newton, equation, sometimes, referred, newton, schrödinger, schrödinger, poisson, equation, nonlinear, modification, schrödinger, equation, with, newtonian, gravitational, potential, where, gravitational, potential, emerges, from, treatment, wave,. The Schrodinger Newton equation sometimes referred to as the Newton Schrodinger or Schrodinger Poisson equation is a nonlinear modification of the Schrodinger equation with a Newtonian gravitational potential where the gravitational potential emerges from the treatment of the wave function as a mass density including a term that represents interaction of a particle with its own gravitational field The inclusion of a self interaction term represents a fundamental alteration of quantum mechanics 1 It can be written either as a single integro differential equation or as a coupled system of a Schrodinger and a Poisson equation In the latter case it is also referred to in the plural form The Schrodinger Newton equation was first considered by Ruffini and Bonazzola 2 in connection with self gravitating boson stars In this context of classical general relativity it appears as the non relativistic limit of either the Klein Gordon equation or the Dirac equation in a curved space time together with the Einstein field equations 3 The equation also describes fuzzy dark matter and approximates classical cold dark matter described by the Vlasov Poisson equation in the limit that the particle mass is large 4 Later on it was proposed as a model to explain the quantum wave function collapse by Lajos Diosi 5 and Roger Penrose 6 7 8 from whom the name Schrodinger Newton equation originates In this context matter has quantum properties while gravity remains classical even at the fundamental level The Schrodinger Newton equation was therefore also suggested as a way to test the necessity of quantum gravity 9 In a third context the Schrodinger Newton equation appears as a Hartree approximation for the mutual gravitational interaction in a system of a large number of particles In this context a corresponding equation for the electromagnetic Coulomb interaction was suggested by Philippe Choquard at the 1976 Symposium on Coulomb Systems in Lausanne to describe one component plasmas Elliott H Lieb provided the proof for the existence and uniqueness of a stationary ground state and referred to the equation as the Choquard equation 10 Contents 1 Overview 1 1 Relation to semi classical and quantum gravity 2 Many body equation and centre of mass motion 3 Significance of effects 4 Quantum wave function collapse 4 1 Problems and open matters 5 See also 6 ReferencesOverview editAs a coupled system the Schrodinger Newton equations are the usual Schrodinger equation with a self interaction gravitational potentialiℏ PS t ℏ2 2 m 2PS V PS m F PS displaystyle i hbar frac partial Psi partial t frac hbar 2 2 m nabla 2 Psi V Psi m Phi Psi nbsp where V is an ordinary potential and the gravitational potential F displaystyle Phi nbsp representing the interaction of the particle with its own gravitational field satisfies the Poisson equation 2F 4p G m PS 2 displaystyle nabla 2 Phi 4 pi G m Psi 2 nbsp Because of the back coupling of the wave function into the potential it is a nonlinear system Replacing F displaystyle Phi nbsp with the solution to the Poisson equation produces the integro differential form of the Schrodinger Newton equation iℏ PS t ℏ2 2 m 2 V G m2 PS t y 2 x y d3y PS displaystyle i hbar frac partial Psi partial t left frac hbar 2 2 m nabla 2 V G m 2 int frac Psi t mathbf y 2 mathbf x mathbf y mathrm d 3 mathbf y right Psi nbsp It is obtained from the above system of equations by integration of the Poisson equation under the assumption that the potential must vanish at infinity Mathematically the Schrodinger Newton equation is a special case of the Hartree equation for n 2 The equation retains most of the properties of the linear Schrodinger equation In particular it is invariant under constant phase shifts leading to conservation of probability and exhibits full Galilei invariance In addition to these symmetries a simultaneous transformationm m m t m 5t x m 3x ps t x m9 2ps m5t m3x displaystyle m to mu m qquad t to mu 5 t qquad mathbf x to mu 3 mathbf x qquad psi t mathbf x to mu 9 2 psi mu 5 t mu 3 mathbf x nbsp maps solutions of the Schrodinger Newton equation to solutions 11 12 The stationary equation which can be obtained in the usual manner via a separation of variables possesses an infinite family of normalisable solutions of which only the stationary ground state is stable 13 14 15 Relation to semi classical and quantum gravity edit The Schrodinger Newton equation can be derived under the assumption that gravity remains classical even at the fundamental level and that the right way to couple quantum matter to gravity is by means of the semiclassical Einstein equations In this case a Newtonian gravitational potential term is added to the Schrodinger equation where the source of this gravitational potential is the expectation value of the mass density operator or mass flux current 16 In this regard if gravity is fundamentally classical the Schrodinger Newton equation is a fundamental one particle equation which can be generalised to the case of many particles see below If on the other hand the gravitational field is quantised the fundamental Schrodinger equation remains linear The Schrodinger Newton equation is then only valid as an approximation for the gravitational interaction in systems of a large number of particles and has no effect on the centre of mass 17 Many body equation and centre of mass motion editIf the Schrodinger Newton equation is considered as a fundamental equation there is a corresponding N body equation that was already given by Diosi 5 and can be derived from semiclassical gravity in the same way as the one particle equation iℏ tPS t x1 xN j 1Nℏ22mj j2 j kVjk xj xk G j k 1Nmjmk d3y1 d3yN PS t y1 yN 2 xj yk PS t x1 xN displaystyle begin aligned i hbar frac partial partial t Psi t mathbf x 1 dots mathbf x N bigg amp sum j 1 N frac hbar 2 2m j nabla j 2 sum j neq k V jk big mathbf x j mathbf x k big amp G sum j k 1 N m j m k int mathrm d 3 mathbf y 1 cdots mathrm d 3 mathbf y N frac Psi t mathbf y 1 dots mathbf y N 2 mathbf x j mathbf y k bigg Psi t mathbf x 1 dots mathbf x N end aligned nbsp The potential Vjk displaystyle V jk nbsp contains all the mutual linear interactions e g electrodynamical Coulomb interactions while the gravitational potential term is based on the assumption that all particles perceive the same gravitational potential generated by all the marginal distributions for all the particles together In a Born Oppenheimer like approximation this N particle equation can be separated into two equations one describing the relative motion the other providing the dynamics of the centre of mass wave function For the relative motion the gravitational interaction does not play a role since it is usually weak compared to the other interactions represented by Vjk displaystyle V jk nbsp But it has a significant influence on the centre of mass motion While Vjk displaystyle V jk nbsp only depends on relative coordinates and therefore does not contribute to the centre of mass dynamics at all the nonlinear Schrodinger Newton interaction does contribute In the aforementioned approximation the centre of mass wave function satisfies the following nonlinear Schrodinger equation iℏ psc t R t ℏ22M 2 G d3R d3y d3z psc t R 2rc y rc z R R y z psc t R displaystyle i hbar frac partial psi c t mathbf R partial t left frac hbar 2 2M nabla 2 G int mathrm d 3 mathbf R int mathrm d 3 mathbf y int mathrm d 3 mathbf z frac psi c t mathbf R 2 rho c mathbf y rho c mathbf z left mathbf R mathbf R mathbf y mathbf z right right psi c t mathbf R nbsp where M is the total mass R is the relative coordinate psc displaystyle psi c nbsp the centre of mass wave function and rc displaystyle rho c nbsp is the mass density of the many body system e g a molecule or a rock relative to its centre of mass 18 In the limiting case of a wide wave function i e where the width of the centre of mass distribution is large compared to the size of the considered object the centre of mass motion is approximated well by the Schrodinger Newton equation for a single particle The opposite case of a narrow wave function can be approximated by a harmonic oscillator potential where the Schrodinger Newton dynamics leads to a rotation in phase space 19 In the context where the Schrodinger Newton equation appears as a Hartree approximation the situation is different In this case the full N particle wave function is considered a product state of N single particle wave functions where each of those factors obeys the Schrodinger Newton equation The dynamics of the centre of mass however remain strictly linear in this picture This is true in general nonlinear Hartree equations never have an influence on the centre of mass Significance of effects editA rough order of magnitude estimate of the regime where effects of the Schrodinger Newton equation become relevant can be obtained by a rather simple reasoning 9 For a spherically symmetric Gaussian PS t 0 r ps2 3 4exp r22s2 displaystyle Psi t 0 r pi sigma 2 3 4 exp left frac r 2 2 sigma 2 right nbsp the free linear Schrodinger equation has the solution PS t r ps2 3 4 1 iℏtms2 3 2exp r22s2 1 iℏtms2 displaystyle Psi t r pi sigma 2 3 4 left 1 frac i hbar t m sigma 2 right 3 2 exp left frac r 2 2 sigma 2 left 1 frac i hbar t m sigma 2 right right nbsp The peak of the radial probability density 4pr2 PS 2 displaystyle 4 pi r 2 Psi 2 nbsp can be found at rp s1 ℏ2t2m2s4 displaystyle r p sigma sqrt 1 frac hbar 2 t 2 m 2 sigma 4 nbsp Now we set the acceleration r p ℏ2m2rp3 displaystyle ddot r p frac hbar 2 m 2 r p 3 nbsp of this peak probability equal to the acceleration due to Newtonian gravity r Gmr2 displaystyle ddot r frac Gm r 2 nbsp using that rp s displaystyle r p sigma nbsp at time t 0 displaystyle t 0 nbsp This yields the relation m3s ℏ2G 1 7 10 58 mkg3 displaystyle m 3 sigma frac hbar 2 G approx 1 7 times 10 58 text m text kg 3 nbsp which allows us to determine a critical width for a given mass value and conversely We also recognise the scaling law mentioned above Numerical simulations 12 1 show that this equation gives a rather good estimate of the mass regime above which effects of the Schrodinger Newton equation become significant For an atom the critical width is around 1022 metres while it is already down to 10 31 metres for a mass of one microgram The regime where the mass is around 1010 atomic mass units while the width is of the order of micrometers is expected to allow an experimental test of the Schrodinger Newton equation in the future A possible candidate are interferometry experiments with heavy molecules which currently reach masses up to 10000 atomic mass units Quantum wave function collapse editThe idea that gravity causes or somehow influences the wavefunction collapse dates back to the 1960s and was originally proposed by Karolyhazy 20 The Schrodinger Newton equation was proposed in this context by Diosi 5 There the equation provides an estimation for the line of demarcation between microscopic quantum and macroscopic classical objects The stationary ground state has a width ofa0 ℏ2Gm3 displaystyle a 0 approx frac hbar 2 Gm 3 nbsp For a well localised homogeneous sphere i e a sphere with a centre of mass wave function that is narrow compared to the radius of the sphere Diosi finds as an estimate for the width of the ground state centre of mass wave function a0 R a01 4R3 4 displaystyle a 0 R approx a 0 1 4 R 3 4 nbsp Assuming a usual density around 1000 kg m3 a critical radius can be calculated for which a0 R R displaystyle a 0 R approx R nbsp This critical radius is around a tenth of a micrometer Roger Penrose proposed that the Schrodinger Newton equation mathematically describes the basis states involved in a gravitationally induced wavefunction collapse scheme 6 7 8 Penrose suggests that a superposition of two or more quantum states having a significant amount of mass displacement ought to be unstable and reduce to one of the states within a finite time He hypothesises that there exists a preferred set of states that could collapse no further specifically the stationary states of the Schrodinger Newton equation A macroscopic system can therefore never be in a spatial superposition since the nonlinear gravitational self interaction immediately leads to a collapse to a stationary state of the Schrodinger Newton equation According to Penrose s idea when a quantum particle is measured there is an interplay of this nonlinear collapse and environmental decoherence The gravitational interaction leads to the reduction of the environment to one distinct state and decoherence leads to the localisation of the particle e g as a dot on a screen Problems and open matters edit Three major problems occur with this interpretation of the Schrodinger Newton equation as the cause of the wave function collapse Excessive residual probability far from the collapse point Lack of any apparent reason for the Born rule Promotion of the previously strictly hypothetical wave function to an observable real quantity First numerical studies 12 15 1 agreeingly find that when a wave packet collapses to a stationary solution a small portion of it seems to run away to infinity This would mean that even a completely collapsed quantum system still can be found at a distant location Since the solutions of the linear Schrodinger equation tend towards infinity even faster this only indicates that the Schrodinger Newton equation alone is not sufficient to explain the wave function collapse If the environment is taken into account this effect might disappear and therefore not be present in the scenario described by Penrose A second problem also arising in Penrose s proposal is the origin of the Born rule To solve the measurement problem a mere explanation of why a wave function collapses e g to a dot on a screen is not enough A good model for the collapse process also has to explain why the dot appears on different positions of the screen with probabilities that are determined by the squared absolute value of the wave function It might be possible that a model based on Penrose s idea could provide such an explanation but there is as yet no known reason that Born s rule would naturally arise from it Thirdly since the gravitational potential is linked to the wave function in the picture of the Schrodinger Newton equation the wave function must be interpreted as a real object Therefore at least in principle it becomes a measurable quantity Making use of the nonlocal nature of entangled quantum systems this could be used to send signals faster than light which is generally thought to be in contradiction with causality It is however not clear whether this problem can be resolved by applying the right collapse prescription yet to be found consistently to the full quantum system Also since gravity is such a weak interaction it is not clear that such an experiment can be actually performed within the parameters given in our universe 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