Vortices and vortex lattices in quantum ferrofluids

Martin, A. M.; Marchant, Neil G.; O’Dell, D. H. J.; Parker, N. G.

doi:10.1088/1361-648x/aa53a6

Cited by 38 publications

(52 citation statements)

References 315 publications

(708 reference statements)

Supporting

Mentioning

Contrasting

Order By: Relevance

“…This discovered, QFM or else Quantum Magnet, vortex flux could also provide a possible physical mechanism for explaining the macroscopic field imprint of magnetic dipoles as shown in fig.2. The effect is similar as described by vortex hydrodynamics [18][19][20], quantum Bose-Einstein condensate ferrofluids [21] and general vortex model theory [22,23] very often encountered in nature from the quantum scale to the macro world [13]. The quantum vortex flux we call, M-field shown in fig.2(a) with red and fig.…”

Section: Resultsmentioning

confidence: 56%

See 1 more Smart Citation

Real time observation of a stationary magneton

et al. 2019

View full text Add to dashboard Cite

The magnetic dipole field geometry of subatomic elementary particles like the electron differs from the classical macroscopic field imprint of a bar magnet. It resembles more like an eight figure or else joint double quantum-dots instead of the classical, spherical more uniform field of a bar magnet. This actual subatomic quantum magnetic field of an electron at rest, is called Quantum Magnet or else a Magneton. It is today verified experimentally by quantum magnetic field imaging methods and sensors like SQUID scanning magnetic microscopy of ferromangets and also seen in Bose-Einstein Condensates (BEC) quantum ferrrofluids experiments. Normally, a macroscale bar magnet should behave like a relative giant Quantum Magnet with identical magnetic dipole field imprint since all of its individual magnetons collectively inside the material, dipole moments are uniformly aligned forming the total net field of the magnet. However due to Quantum Decoherence (QDE) phenomenon at the macroscale and macroscopic magnetic field imaging sensors limitations which cannot pickup these rapid quantum magnetization fluctuations, this field is masked and not visible at the macroscale. By using the relative inexpensive submicron resolution Ferrolens quantum magnetic optical superparamagnetic thin film sensor for field real time imaging and method we have researched in our previous publications, we can actually make this net magneton field visible on macroscale magnets. We call this net total field herein, Quantum Field of Magnet (QFM) differentiating it therefore from the field of the single subatomic magneton thus quantum magnet. Additionally, the unique potential of the Ferrolens device to display also the magnetic flux lines of this macroscopically projected giant Magenton gives us the opportunity for the first time to study the individual magnetic flux lines geometrical pattern that of a single subatomic magneton. We describe this particular magnetic flux of the magneton observed, quantum magnetic flux. Therefore an astonishing novel observation has been made that the Quantum Magnetic Field of the Magnet-Magneton (QFM) consists of a dipole vortex shaped magnetic flux geometrical pattern responsible for creating the classical macroscopic N-S field of magnetism as a tension field between the two polar quantum flux vortices North and South poles. A physical interpretation of this quantum decoherence mechanism observed is analyzed and presented and conclusions made showing physical evidence of the quantum origin irrotational and therefore conservative property of magnetism and also demonstrating that ultimately magnetism at the quantum level is an energy dipole vortex phenomenon.

show abstract

Section: Resultsmentioning

confidence: 56%

“…The ferrolens optic display device is an electric insulator at all temperatures therefore not a superconductor. In addition we tested rigorously for superfluidic behavior concerning quantization of magnetic vortices generation at different values of induced angular momentum [21] [39] without any observable effect.…”

Section: Quantum Magnetmentioning

confidence: 99%

Real time observation of a stationary magneton

et al. 2019

View full text Add to dashboard Cite

show abstract

“…Finally, by t = 5000ω −1 ⊥ the vortices have entered the condensate and have relaxed into a triangular Abrikosov vortex lattice. Several theoretical studies have indicated that this may be the ground state for a system of vortices in (non-)dipolar BECs at finite rotation frequencies [35,36,38,42,43,46,70]. In nondipolar BECs subject to a ramping up of the trapping rotation frequency, a vortex lattice is seen to form following a period of evolution of the nondipolar GPE at constant rotation frequency after the vortex instability has been triggered [66,71].…”

Section: Dipolar Gross-pitaevskii Equation Simulationsmentioning

confidence: 99%

“…Examples of the methods that experimentalists have used to create vortices include: direct imprinting of phase defects into the condensate [29], rotation of either a laser * srivatsa.badariprasad@unimelb.edu.au beam stirrer or the external trapping potential of the condensate itself [30,31], dragging a barrier through the condensate [27,28,32], applying a rapidly oscillating perturbation to the trapping potential [25], Bose-condensing a rotating normal Bose gas [33], and utilising the Kibble-Zurek mechanism to trigger the formation of topological defects [34]. While vortices have not yet been experimentally observed in dipolar BECs, there exists an extensive body of theoretical research regarding vortex structure, vortex lattice structure, and vortex-vortex interactions in these systems [35][36][37][38][39][40][41][42][43][44][45][46].…”

Section: Introductionmentioning

confidence: 99%

Vortex lattice formation in dipolar Bose-Einstein condensates via rotation of the polarization

et al. 2019

View full text Add to dashboard Cite

The behaviour of a harmonically trapped dipolar Bose-Einstein condensate with its dipole moments rotating at angular frequencies lower than the transverse harmonic trapping frequency is explored in the co-rotating frame. We obtain semi-analytical solutions for the stationary states in the Thomas-Fermi limit of the corresponding dipolar Gross-Pitaevskii equation and utilise linear stability analysis to elucidate a phase diagram for the dynamical stability of these stationary solutions with respect to collective modes. These results are verified via direct numerical simulations of the dipolar Gross-Pitaevskii equation, which demonstrate that dynamical instabilities of the corotating stationary solutions lead to the seeding of vortices that eventually relax into a triangular lattice configuration. Our results illustrate that rotation of the dipole polarization represents a new route to vortex formation in dipolar Bose-Einstein condensates. arXiv:1906.08664v2 [cond-mat.quant-gas]

show abstract

“…Dipolar Bose-Einstein condensates (BECs) have proved to be a unique, highly-controllable platform for studying the interplay of quantum many-body physics and magnetic interactions [1][2][3][4][5][6]. Compared to conventional condensates, in which the atoms undergo shortrange, contact-like, isotropic inter-particle interactions, a dipolar BEC also enjoys a long-range anisotropic dipoledipole interaction (DDI) [7][8][9][10][11]. While the first dipolar BECs were realised in a gas of 52 Cr [1,2], atoms with larger magnetic dipole moments such as 164 Dy [4,6] and 168 Er [5] have now been cooled to form strongly dipolar BECs.…”

mentioning

confidence: 99%

Instability of Rotationally Tuned Dipolar Bose-Einstein Condensates

et al. 2019

View full text Add to dashboard Cite

The possibility of effectively inverting the sign of the dipole-dipole interaction, by fast rotation of the dipole polarization, is examined within a harmonically trapped dipolar Bose-Einstein condensate. Our analysis is based on the stationary states in the Thomas-Fermi limit, in the corotating frame, as well as direct numerical simulations in the Thomas-Fermi regime, explicitly accounting for the rotating polarization. The condensate is found to be inherently unstable due to the dynamical instability of collective modes. This ultimately prevents the realization of robust and long-lived rotationally tuned states. Our findings have major implications for experimentally accessing this regime.

show abstract

Vortices and vortex lattices in quantum ferrofluids

Cited by 38 publications

References 315 publications

Real time observation of a stationary magneton

Real time observation of a stationary magneton

Vortex lattice formation in dipolar Bose-Einstein condensates via rotation of the polarization

Instability of Rotationally Tuned Dipolar Bose-Einstein Condensates

Contact Info

Product

Resources

About