Transport of magnetically sensitive atoms in a magnetic environment
- URL: http://arxiv.org/abs/2410.06640v3
- Date: Thu, 23 Jan 2025 13:45:28 GMT
- Title: Transport of magnetically sensitive atoms in a magnetic environment
- Authors: Davlet Kumpilov, Ivan Pyrkh, Ivan Cojocaru, Polina Trofimova, Arjuna Rudnev, Vladimir Khlebnikov, Pavel Aksentsev, Ayrat Ibrahimov, Kirill Frolov, Sergey Kuzmin, Anna Zykova, Daniil Pershin, Vladislav Tsyganok, Alexey Akimov,
- Abstract summary: Rare-earth ultracold atoms are particularly appealing due to their numerous Fano-Feshbach resonances and magnetic dipole moments in the ground state.
We demonstrate that in case of the transport of magnetic atoms the magnetic field can be directly measured and adjusted to reduce additional losses.
This approach allows to transfer over 85% of the atoms from the main chamber to the scientific chamber, located 38 cm away with moderate laser power of 26 W without atomic polarization decay.
- Score: 0.0
- License:
- Abstract: Among interesting applications of cold atoms, quantum simulations attract a lot of attention. In this context, rare-earth ultracold atoms are particularly appealing for such simulators due to their numerous Fano-Feshbach resonances and magnetic dipole moments in the ground state. Creating a quantum gas microscope requires a large optical access that may be achieved using transport of atoms between separate vacuum volumes. We demonstrate that in case of the transport of magnetic atoms the magnetic field can be directly measured and adjusted to reduce additional losses after the transport therefore increasing the efficiency of subsequent evaporation cooling. This approach allows to transfer over 85% of the atoms from the main chamber to the scientific chamber, located 38 cm away with moderate laser power of 26 W without atomic polarization decay.
Related papers
- Light-induced fictitious magnetic fields for quantum storage in cold atomic ensembles [20.77204722797697]
We have demonstrated that optically generated fictitious magnetic fields can be utilized to extend the lifetime of quantum memories in cold atomic ensembles.
The advantage of the use of fictitious magnetic fields for quantum storage stems from the speed and spatial precision that these fields can be synthesized.
arXiv Detail & Related papers (2024-06-12T14:20:20Z) - Loading atoms from a large magnetic trap to a small intra-cavity dipole
trap [0.0]
We show that an optimized loading of a cold ensemble of rubidium-87 atoms from a magnetic trap can be efficient despite the large volume mismatch of the traps.
We demonstrate state-independent trapping by applying a repumper laser.
arXiv Detail & Related papers (2023-10-06T12:33:14Z) - Experimental implementation of laser cooling of trapped ions in strongly
inhomogeneous magnetic fields [0.0]
We demonstrate the Doppler laser cooling of ions confined in a linear Paul trap in the presence of a strong quadrupolar magnetic field generated by two permanent ring magnets.
Magnetic field gradients of 800 to 1600 G/mm give rise to a highly position-dependent Zeeman shift on the energy levels of the trapped ions.
This work forms the basis for developing hybrid trapping experiments for cold ions and neutral molecules that consist of an ion and a magnetic trap to study cold interactions between these species.
arXiv Detail & Related papers (2023-09-06T22:09:33Z) - An anti-maser for quantum-limited cooling of a microwave cavity [58.720142291102135]
We experimentally demonstrate how to generate a state in condensed matter at moderate cryogenic temperatures.
This state is then used to efficiently remove microwave photons from a cavity.
Such an "anti-maser" device could be extremely beneficial for applications that would normally require cooling to millikelvin temperatures.
arXiv Detail & Related papers (2023-07-24T11:12:29Z) - Imaging magnetism evolution of magnetite to megabar pressure range with
quantum sensors in diamond anvil cell [57.91882523720623]
We develop an in-situ magnetic detection technique at megabar pressures with high sensitivity and sub-microscale spatial resolution.
We observe the macroscopic magnetic transition of Fe3O4 in the megabar pressure range from strong ferromagnetism (alpha-Fe3O4) to weak ferromagnetism (beta-Fe3O4) and finally to non-magnetism (gamma-Fe3O4)
The presented method can potentially investigate the spin-orbital coupling and magnetism-superconductivity competition in magnetic systems.
arXiv Detail & Related papers (2023-06-13T15:19:22Z) - Enhanced dark-state sideband cooling in trapped atoms via
photon-mediated dipole-dipole interactions [4.915587669065746]
We present an enhanced dark-state sideband cooling in trapped atoms utilizing photon-mediated dipole-dipole interactions among them.
By placing the atoms at the magic interparticle distances, we manifest an outperformed cooling behavior in the target atom.
Our results provide insights to subrecoil cooling of atoms with collective and light-induced long-range dipole-dipole interactions, and pave the way toward implementing genuine quantum operations in multiple quantum registers.
arXiv Detail & Related papers (2022-10-12T13:33:20Z) - Quantum-limited millimeter wave to optical transduction [50.663540427505616]
Long distance transmission of quantum information is a central ingredient of distributed quantum information processors.
Current approaches to transduction employ solid state links between electrical and optical domains.
We demonstrate quantum-limited transduction of millimeter-wave (mmwave) photons into optical photons using cold $85$Rb atoms as the transducer.
arXiv Detail & Related papers (2022-07-20T18:04:26Z) - Ultrastrong magnetic light-matter interaction with cavity mode
engineering [0.0]
We present techniques to create resonators with ultrasmall mode volume and ultrahigh quality factor.
We show that it is possible to achieve an arbitrarily small mode volume only limited by materials or fabrication with minimal quality-factor degradation.
These methods enable new applications from high-cooperativity microwave-spin coupling in quantum computing or compact electron paramagnetic resonance sensors to fundamental science such as dark matter searches.
arXiv Detail & Related papers (2021-08-30T14:26:33Z) - Demonstration of electron-nuclear decoupling at a spin clock transition [54.088309058031705]
Clock transitions protect molecular spin qubits from magnetic noise.
linear coupling to nuclear degrees of freedom causes a modulation and decay of electronic coherence.
An absence of quantum information leakage to the nuclear bath provides opportunities to characterize other decoherence sources.
arXiv Detail & Related papers (2021-06-09T16:23:47Z) - Photon Condensation and Enhanced Magnetism in Cavity QED [68.8204255655161]
A system of magnetic molecules coupled to microwave cavities undergoes the equilibrium superradiant phase transition.
The effect of the coupling is first illustrated by the vacuum-induced ferromagnetic order in a quantum Ising model.
A transmission experiment is shown to resolve the transition, measuring the quantum electrodynamical control of magnetism.
arXiv Detail & Related papers (2020-11-07T11:18:24Z) - Quantum coherent spin-electric control in a molecular nanomagnet at
clock transitions [57.50861918173065]
Electrical control of spins at the nanoscale offers architectural advantages in spintronics.
Recent demonstrations of electric-field (E-field) sensitivities in molecular spin materials are tantalising.
E-field sensitivities reported so far are rather weak, prompting the question of how to design molecules with stronger spin-electric couplings.
arXiv Detail & Related papers (2020-05-03T09:27:31Z)
This list is automatically generated from the titles and abstracts of the papers in this site.
This site does not guarantee the quality of this site (including all information) and is not responsible for any consequences.