Some scientific procedures utilize a thermal beam of atoms and sometimes it is advantageous to have a more slowly moving beam of atoms, and in some cases the atoms from the beam are captured, and in some cases the atoms in the beam are used for other applications (e.g., spectroscopy). A common method of generating a beam of atoms uses an evaporator with an outlet. In some cases, the outlet is a thin-walled pinhole, an array of tubes, one or several cylindrical channels, a slit or array of slits, a microchannel plate, or a combination of these items. Atoms are evaporated and exit the evaporator at high speed through the outlet. Atomic collectors typically require atoms to be at low speed in order to be captured, thus they must be slowed between the evaporator and the collector. Other applications for the beam also require low speeds. The Zeeman slower is a well-known method of slowing a beam of atoms, comprising a laser beam and a magnetic field. The laser beam shines into the beam of atoms opposite their direction of travel and is tuned to resonate with a quantum transition in the atoms. When a photon from the laser is absorbed, the atom loses momentum and slows down. When averaged over a large number of absorption-emission cycles, the process of absorbing and re-emitting photons causes a net slowing of the atoms. Due to the Doppler effect, the resonance frequency for a given atom as measured in the lab frame (i.e., the frame for the laser beam) depends on the velocity for the atom. If a fixed frequency laser is used for the cooling, then as the atoms slow down, the frequency difference between the laser and the atomic resonance increases, which causes the photon scattering rate to decrease. The acceleration experienced by the atom depends on this rate, so as the scattering rate decreases, the acceleration decreases. To avoid this problem, a magnetic field is used. The magnetic field counteracts the changing Doppler shift by modifying the resonance frequency of the atoms (e.g., the Zeeman effect). This approach allows the laser beam to continue slowing the atoms as they themselves slow down. For atomic transitions with linear Zeeman shifts the required magnetic field can be derived from a resonance condition: ν0±(μ/h)B=νL=u/λ where ν0 (νL) is the atomic (laser) frequency, μ is the magnetic moment for the transition, B is the amplitude for the magnetic flux density, λ is the wavelength for the atomic transition, and u is the instantaneous speed for the atom. Ideally, the field is axial (e.g., the field lines are collinear with the direction of travel for the atomic beam). Atoms with transitions that have different dependencies of Zeeman shifts could also be slowed by tailoring the magnetic field appropriately to maintain resonance as the atoms are slowed.
Typically the magnetic field is produced with electromagnets. Electromagnets allow for easy customization of the magnetic field to the desired shape. However, electromagnets take up a great deal of space and require power and cooling systems. Although electromagnets can be housed inside vacuum chambers, this approach is impractical for Zeeman slowers given the heat loads and vacuum outgassing generated by the requisite electromagnets. Hence the windings are usually housed outside the vacuum chamber where the atomic beam travels. This results in a large and power-hungry device, unsuitable for some applications.
Various embodiments of the invention are disclosed in the following detailed description and the accompanying drawings.
The invention can be implemented in numerous ways, including as a process; an apparatus; a system; a composition of matter; a computer program product embodied on a computer readable storage medium; and/or a processor, such as a processor configured to execute instructions stored on and/or provided by a memory coupled to the processor. In this specification, these implementations, or any other form that the invention may take, may be referred to as techniques. In general, the order of the steps of disclosed processes may be altered within the scope of the invention. Unless stated otherwise, a component such as a processor or a memory described as being configured to perform a task may be implemented as a general component that is temporarily configured to perform the task at a given time or a specific component that is manufactured to perform the task. As used herein, the term processor refers to one or more devices, circuits, and/or processing cores configured to process data, such as computer program instructions.
A detailed description of one or more embodiments of the invention is provided below along with accompanying figures that illustrate the principles of the invention. The invention is described in connection with such embodiments, but the invention is not limited to any embodiment. The scope of the invention is limited only by the claims and the invention encompasses numerous alternatives, modifications and equivalents. Numerous specific details are set forth in the following description in order to provide a thorough understanding of the invention. These details are provided for the purpose of example and the invention may be practiced according to the claims without some or all of these specific details. For the purpose of clarity, technical material that is known in the technical fields related to the invention has not been described in detail so that the invention is not unnecessarily obscured.
A permanent magnet axial field Zeeman slower is disclosed. The Zeeman slower comprises a set of permanent magnets specifically designed to produce the desired magnetic field shape and a bore for the travel of atoms within the magnetic field. The magnets are small, passive (e.g., require no power or cooling), and vacuum compatible. The Zeeman slower comprises three or more magnets with the axis of magnetization aligned parallel or at an angle to the axis of travel of the atoms moving through the Zeeman slower. The magnets can be placed in a rotationally symmetric pattern in the transverse plane, e.g., at positions of 360°/n, where n is the number of magnets. This approach maximizes the uniformity of the magnetic field in the transverse plane at a given axial position. Alternatively, the magnets can be placed in a rotationally non-symmetric pattern in the transverse plane, i.e., at a variety of angles. This approach allows tailoring the magnetic field shape in the transverse plane at a given axial position. In some embodiments, the Zeeman slower additionally comprises a magnetic shield (e.g., for isolating the magnetic field of the slower) and a transverse cooling apparatus (e.g., for reducing the transverse speed of traveling atoms). In various embodiments, the magnetic shield comprises a material with high magnetic permeability, multiple layers—a mix of high permeability material (e.g., mu metal) with a lower permeability (e.g., soft iron), one or more layers of one or more materials, a nano-technology coating, or any other appropriate shield. In some embodiments, the magnetic shield alters the shape, the field direction, or the magnitude of the Zeeman slower magnetic field inside the bore. In various embodiments, the magnetic shield alters an axial position for the zero-crossings of the magnetic fields, or the magnitude or shape of the associated maxima in the magnetic field amplitude. In some embodiments, the magnetic shield improves the uniformity of the Zeeman slower magnetic field inside the bore. In some embodiments, the one or more tapered magnets are configured to make a magnetic field magnitude change quickly outside the slower (e.g., faster than inverse distance squared). In some embodiments, the magnetic shield comprises of one or more separable pieces.
In some embodiments, the slower comprises a single or multi-layer thermal or radiative shield that thermally isolates the slower. The thermal or radiative shield allows minimizing the separation between the slower and the evaporator which, in turn, enables compact devices or for evaporators emitting poorly collimated beams. In addition, because the slower is close to the evaporator the atomic beam is only allowed to spread minimally before it enters the slower.
In some embodiments, the transverse cooler is tilted in angle relative to the main axis of the slower This approach is useful for some applications (e.g., separating the slowed atomic beam from residual non-slowed atoms; reducing the scattered light that reaches subsequent devices, and allowing the slowing light to pass through the slower without passing through the transverse cooler).
Previously developed permanent magnet Zeeman slowers have utilized a transverse magnetic field for the axial slowing, resulting in lower efficiency. The slower described herein utilizes an axial magnetic field for slowing, resulting in higher efficiency. The axial magnetic field is established using permanent magnets without field lines reversing direction or varying significantly in density as the transverse position increases away from the axis.
In various embodiments, the bore is configured to provide one or more reference features or one or more mounting surfaces for optics used for a transverse cooler. In some embodiments, the slower is mounted in a vacuum chamber. In some embodiments, the bore of the atomic slower is configured to allow a laser beam to enter. For example, along the axis of the atomic beam and/or transverse to the atomic beam. In some embodiments, the bore is configured to provide one or more reference features or one or more mounting surfaces for the one or more tapered permanent magnets. The reference features or surfaces allow for setting the axial and transverse positions and rotational orientations for the magnets. In some embodiments, the bore is configured to provide one or more reference features or one or more mounting surfaces for the magnetic shield or is used by a secondary device to mount or position the magnetic shield. The features or surfaces can comprise edges, the surface or planar or non-planar shapes, or markers. For example, the outer surface of a bore with a circular cross-section can be used to make a magnetic shield with a circular cross-section concentric with the axis of the bore while an edge on the outer surface of the bore can be used to set the axial position of the shield. The reference features or mounting surfaces enable easy and precise assembly or construction of the slower.
The atomic beam enters Zeeman slower 102 and atoms are slowed as they travel through the Zeeman slower (e.g., from left to right in
In some embodiments, the methods described are used in a reverse configuration where the magnetic field and the laser beam are used to accelerate the atomic beam rather than slow the atomic beam. To accelerate the atomic beam the laser and atoms travel in the same direction rather than in opposite directions, as used in the slower. The atom accelerator moves the atoms to higher speed and narrows the longitudinal velocity distribution. Faster moving atoms with a narrow velocity distribution, or just narrower velocity distributions can be advantageous for applications such as atomic interferometers gyroscopes, clocks, scientific tests, etc. and some environments such as moving platforms, in space, etc.
Atomic trap 106 comprises an atomic trap that provides additional cooling and spatial confinement of atoms in the atomic beam. In some embodiments, atomic trap 106 comprises a magneto-optical trap. In some embodiments, atomic trap 106 comprises one or several focused or collimated laser beams. In some embodiments, atomic trap 106 provides only spatial confinement (i.e., is a conservative trap). In some embodiments, atomic trap 106 uses magnetic or electric fields to confine the atoms. In some embodiments, atomic trap 106 provides spatial confinement and cooling along one, two, or three dimensions. In some embodiments, atomic trap 106 captures atoms (e.g., reduces their speed to near absolute zero). In some embodiments, atomic trap 106 can only capture atoms if they are already traveling below a certain speed, e.g., 20 m/s. In some embodiments, atomic trap 106 is used to capture atoms for use in further applications. In various embodiments, atomic trap 106 is used to capture atoms for experiments on Bose-Einstein condensation, for atomic clocks, for atom interferometers, for spectroscopy, or for any other appropriate purpose.
In the example shown, magnetic shield 400 (shown in cross-section at both the upper and lower parts of the drawing) comprises a magnetic shield for isolating the Zeeman slower from external magnetic fields and for causing the magnetic field to fall quickly after the slower ends. Magnet 402 and magnet 406 comprise permanent magnets. In the example shown, the Zeeman slower comprises four magnets, two of which are not visible in the cross-section. In various embodiments, the Zeeman slower comprises 3, 4, 5, 6, 8, 12, or any other appropriate number of magnets. Bore 404 comprises a bore for confining an atomic beam. In the example shown, atomic beam 408 comprises an atomic beam traveling down the length of the Zeeman slower and being slowed by laser 410.
In the example shown, magnet 402 and magnet 406 are positioned with their long axes angled toward atomic beam 408 as the beam progresses from left to right through the slower. In some embodiments, magnet 402 and magnet 406 are positioned with their long axes angled away from atomic beam 408 as the beam propagates from left to right through the slower. In some embodiments, magnet 402 and magnet 406 are mounted on shaped supports mounted on bore 404, holding them in the positions shown. In some embodiments, magnet 402 and magnet 406 are mounted on external supports holding them in the positions shown. In the example shown, both the shape of the magnets and the angle that the magnets are held are tuned in order to produce the desired magnetic field shape. In some embodiments, the angle comprises an angle of a magnet with respect to the axis of the bore of a Zeeman slower. In some embodiments, magnet 402 and magnet 406 are rotated about their long axis.
Although the foregoing embodiments have been described in some detail for purposes of clarity of understanding, the invention is not limited to the details provided. There are many alternative ways of implementing the invention. The disclosed embodiments are illustrative and not restrictive.
This invention was made with government support under contract #HR0011-11-C-0072 awarded by Darpa. The government has certain rights in the invention.
Number | Name | Date | Kind |
---|---|---|---|
3919678 | Penfold | Nov 1975 | A |
4701737 | Leupold | Oct 1987 | A |
5014032 | Aubert | May 1991 | A |
5098619 | Facaros | Mar 1992 | A |
6476383 | Esslinger et al. | Nov 2002 | B1 |
20020117612 | Kumagai et al. | Aug 2002 | A1 |
20090128272 | Hills | May 2009 | A1 |
20100012826 | Miteva et al. | Jan 2010 | A1 |
20110148297 | Yasuda et al. | Jun 2011 | A1 |
Entry |
---|
Lison et al, “High-Brilliance Zeeman-Slowed Cesium Atomic Beam”, Physical Review A, vol. 61, 013405, 1999. |
Oates et al, “A Diode-Laser Optical Frequency Standard Based on Laser-Cooled Ca Atoms; Sub-Kilohertz Spectroscopy by Optical Shelving Detection”, European Physical Journal D, 449-460 (1999). |
D'Amore et al, “Feasibility of New Nanolayered Transparent Thin Films for Active Shielding of Low Frequency Magnetic Field”, International Symposium on Electromagnetic Compatibility EMC 2005, vol. 3, p. 900-905, 2005. |
Ramirez-Serrano et al, “Multistage Two-Dimensional Magneto-Optical Trap as a Compact Cold Atom Beam Source”, Optics Letters, vol. 31 No. 6, Mar. 15, 2006. |
Kondo et al, “Influence of the Magnetic Field Gradient on the Extraction of Slow Sodium Atoms Outside the Solenoid in the Zeeman Slower”, Jpn. J. Appl. Phys. vol. 36 (1997) p. 905-909. |
Cheiney, et al, “A Zeeman Slower Design With Permanent Magnets in a Halbach Configuration”, Review of Scientific Instruments 82, 063115, 2011. |
Chieney et al, “A Zeeman Slower Design With Permanent Magnets in a Halbach Configuration”, Review of Scientific Instruments 82, 063115, 2011. |
Kondo et al, “Influence of the Magnetic Field Gradient on the Extraction of Slow Sodium Atoms Outside the Solenoid in the Zeeman Slower”, Jpn. J. Appl. Phys, vol. 36, (1997), pp. 905-909. |