Dark energy effects in the Schrödinger-Newton approach
The Schrödinger-Newton equation is a proposed model to explain the localization of macroscopic particles by suppressing quantum dispersion with the particle’s own gravitational attraction. On cosmic scales, however, dark energy also acts repulsively, as witnessed by the accelerating rate of universa...
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sg-ntu-dr.10356-1454942023-02-28T19:27:36Z Dark energy effects in the Schrödinger-Newton approach Kelvin Onggadinata, Kelvin Lake, Matthew James Paterek, Tomasz School of Physical and Mathematical Sciences Majulab @ NTU Science::Physics Dark Energy Schrödinger-Newton The Schrödinger-Newton equation is a proposed model to explain the localization of macroscopic particles by suppressing quantum dispersion with the particle’s own gravitational attraction. On cosmic scales, however, dark energy also acts repulsively, as witnessed by the accelerating rate of universal expansion. Here, we introduce the effects of dark energy in the form of a cosmological constant Λ, that drives the late-time acceleration of the Universe, into the Schrödinger-Newton approach. We then ask in which regime dark energy dominates both canonical quantum diffusion and gravitational self-attraction. It turns out that this happens for sufficiently delocalized objects with an arbitrary mass and that there exists a minimal delocalization width of about 67 m. While extremely macroscopic from a quantum perspective, the value is in principle accessible to laboratories on Earth. Hence, we analyze, numerically, how the dynamics of an initially spherical Gaussian wave packet is modified in the presence of Λ>0. A notable feature is the gravitational collapse of part of the wave packet, in the core region close to the center of mass, accompanied by the accelerated expansion of the more distant shell surrounding it. The order of magnitude of the distance separating collapse from expansion matches analytical estimates of the classical turnaround radius for a spherically symmetric body in the presence of dark energy. However, the time required to observe these modifications is astronomical. They can potentially be measured only in physical systems simulating a high effective cosmological constant, or, possibly, via their effects on the inflationary universe. Ministry of Education (MOE) Published version We thank Sri Devi Wijaya for discussions. This work was supported by Singapore Ministry of Education Academic Research Fund Tier 1 Project No. RG106/17 and Polish National Agency for Academi Exchange NAWA Project No. PPN/PPO/2018/1/00007/U/00001. Both Kelvin acknowledge support from Nanyang Technological University under the Undergraduate Research Experience on Campus (URECA) program.M. L. thanks Nanyang Technological University for hospitality during the preparation of the manuscript. 2020-12-23T01:58:30Z 2020-12-23T01:58:30Z 2020 Journal Article Kelvin, Onggadinata, K., Lake, M. J., & Paterek, T. (2020). Dark energy effects in the Schrödinger-Newton approach. Physical Review D, 101(6), 063028-. doi:10.1103/PhysRevD.101.063028 2470-0010 https://hdl.handle.net/10356/145494 10.1103/PhysRevD.101.063028 6 101 en RG106/17 Physical Review D © 2020 American Physical Society. All rights reserved. This paper was published in Physical Review D and is made available with permission of American Physical Society. application/pdf |
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Science::Physics Dark Energy Schrödinger-Newton Kelvin Onggadinata, Kelvin Lake, Matthew James Paterek, Tomasz Dark energy effects in the Schrödinger-Newton approach |
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The Schrödinger-Newton equation is a proposed model to explain the localization of macroscopic particles by suppressing quantum dispersion with the particle’s own gravitational attraction. On cosmic scales, however, dark energy also acts repulsively, as witnessed by the accelerating rate of universal expansion. Here, we introduce the effects of dark energy in the form of a cosmological constant Λ, that drives the late-time acceleration of the Universe, into the Schrödinger-Newton approach. We then ask in which regime dark energy dominates both canonical quantum diffusion and gravitational self-attraction. It turns out that this happens for sufficiently delocalized objects with an arbitrary mass and that there exists a minimal delocalization width of about 67 m. While extremely macroscopic from a quantum perspective, the value is in principle accessible to laboratories on Earth. Hence, we analyze, numerically, how the dynamics of an initially spherical Gaussian wave packet is modified in the presence of Λ>0. A notable feature is the gravitational collapse of part of the wave packet, in the core region close to the center of mass, accompanied by the accelerated expansion of the more distant shell surrounding it. The order of magnitude of the distance separating collapse from expansion matches analytical estimates of the classical turnaround radius for a spherically symmetric body in the presence of dark energy. However, the time required to observe these modifications is astronomical. They can potentially be measured only in physical systems simulating a high effective cosmological constant, or, possibly, via their effects on the inflationary universe. |
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School of Physical and Mathematical Sciences |
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School of Physical and Mathematical Sciences Kelvin Onggadinata, Kelvin Lake, Matthew James Paterek, Tomasz |
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Article |
| author |
Kelvin Onggadinata, Kelvin Lake, Matthew James Paterek, Tomasz |
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Kelvin |
| title |
Dark energy effects in the Schrödinger-Newton approach |
| title_short |
Dark energy effects in the Schrödinger-Newton approach |
| title_full |
Dark energy effects in the Schrödinger-Newton approach |
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Dark energy effects in the Schrödinger-Newton approach |
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Dark energy effects in the Schrödinger-Newton approach |
| title_sort |
dark energy effects in the schrödinger-newton approach |
| publishDate |
2020 |
| url |
https://hdl.handle.net/10356/145494 |
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