RU2752462C1 - Atomic beam zeeman moderator - Google Patents

Abstract

FIELD: quantum electronics.

SUBSTANCE: invention relates to the field of quantum electronics, devices for generating a non-uniform magnetic field profile and can be used in atomic-beam frequency standards with beams, for example, strontium, rubidium or cesium. The Zeeman moderator (ZM) of the atomic beam includes an ultrahigh vacuum tube with atomic and counterpropagating laser beams directed along its axis and a block for forming an inhomogeneous magnetic field profile attached to the tube and differs in that the forming unit consists of split half-bases with bulkheads, the planes of which perpendicular to the axis of the atomic beam, while the split semi-bases with bulkheads are made of non-magnetic material, between the bulkheads, by rotating the half-bases around the vacuum tube, sections of the solenoid are wound to provide the required gradient and direction of the magnetic field, while the step of placing the bulkheads is determined by the length of the sections of the rectangular section of the winding of the solenoid of the magnetic field profile forming unit, which connect the half-bases into a complete moderator structure.

EFFECT: invention simplifies the placement of the ZM solenoid with a current on the vacuum part of the installation without breaking the ultra-high vacuum, ensures strict adherence to the calculated values of the magnetic field profiles and flexibility of setting ZM.

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Description

The proposed invention relates to the field of quantum electronics, devices for generating a non-uniform magnetic field profile, and can be used in atomic-beam frequency standards with beams, for example, strontium, rubidium or cesium.

The principle of operation of the Zeeman moderator of an atomic beam (ЗЗ) is based on the slowing down of a thermal atomic beam passing along the ЗЗ axis by a counterpropagating laser beam. The deceleration efficiency is provided by the degree of monotonicity of the inhomogeneous magnetic field and the action of a laser beam counterpropagating to the atomic beam, which leads to compensation for the Doppler shift by compensating by changing the Zeeman shift. Those. the profile of the resonant magnetic field along the ZZ should correspond to the gradient of the Doppler shift.

The main one today is the method of realizing the resonance profile of the magnetic field using a solenoid with a current, previously placed before annealing and pumping out of the supervacuum system on the pipe - part of this vacuum system.

In this method, an easy-to-implement solenoid made of a wire with a current is used, which is placed on the ZZ pipe, which is part of a supervacuum system, for example, an atomic spectroscope. The solenoid has a relatively small number of turns - 200-400, which are a multilayer structure, the winding method of which provides the necessary gradient and direction of the magnetic field. This gradient cannot be realized without exact observance of the longitudinal section with exact observance of the positions of the turns. Since any solenoid that creates a gradient magnetic field can be divided into a sequence of rectangular sections, it is possible to introduce thin bulkheads between these sections and wind rectangular coils without breaking the ultra-high vacuum, which significantly reduces the complexity of the assembly, and control of the number of turns, as well as the correspondence of the positions of the turns calculated. Therefore, a special prefabricated frame is needed that will allow easy placement of the solenoid loops around the vacuum tube without breaking the ultra-high vacuum. The implementation of the solenoid using a frame with the implementation of winding "in place" according to the spindle principle without removing the pipe section will speed up the process of creating a vacuum spectroscope and an atomic clock as a whole.

Known ZZ (Patent No.: RU (11) 2490836 (13) C1, Date of Patent: 05/12/2012), which is an analogue of the proposed invention, containing a block for generating an inhomogeneous magnetic field consists of a solenoid designed to form an inhomogeneous magnetic field, and its source power supply operating in continuous mode. The source of the atomic beam and the solenoid of the unit for the formation of an inhomogeneous magnetic field are located in an evacuated volume, the required degree of pressure in which is maintained by a vacuum pump.

However, in the specified ZZ, the placement of the unit for forming the profile of an inhomogeneous magnetic field directly in the evacuated volume is used, which entails the complexity of its placement, the impossibility of modifying the ZZ without seriously disturbing the ultrahigh vacuum of the working installation.

In addition, it is known ZZ (Patent No: EP 1871149 A1, Date of Patent: Dec. 26, 2007), which is a prototype of the present invention and contains a solenoid located on a vacuum tube, the inner channel has a cross section perpendicular to the longitudinal axis, while the area of the transverse the section of the inner channel increases monotonically along the longitudinal axis in a part of the cooling section.

However, this device uses the placement of a solenoid with a ZZ current on a vacuum tube, which provides an increased complexity of restructuring or optimization, modifying the magnetic field profile on the axis, and there is no possibility to change the structure of the solenoid without removing the ZZ section from the vacuum system.

The objective of the present invention is to eliminate the disadvantages of the prototype.

The technical result obtained from the implementation of the invention is to simplify the placement of the ZZ solenoid with a current on the vacuum part of the installation without breaking the ultrahigh vacuum, ensures strict adherence to the calculated values of the magnetic field profiles and the flexibility of setting the ZZ.

The stated technical result is achieved by the fact that the Zeeman moderator of the atomic beam includes an ultrahigh vacuum tube with atomic and counterpropagating laser beams directed along its axis and a block for forming an inhomogeneous magnetic field profile attached to the tube. The forming unit consists of split half-bases with bulkheads, the planes of which are perpendicular to the axis of the atomic beam, while the split half-bases with bulkheads are made of non-magnetic material. Solenoid sections are wound between the bulkheads by rotating the half-bases around the vacuum tube. Moreover, the step of placing the bulkheads is determined by the length of the sections of the rectangular section of the winding of the solenoid of the magnetic field profile forming unit, which connect the half-bases into the finished moderator structure.

The invention is illustrated by drawings.

FIG. 1 shows a drawing of the half-base of the ZZ with bulkheads.

in FIG. 2 shows a drawing of the half-base of the ZZ with bulkheads with an example of the arrangement of the windings of the parts of the solenoid with current.

in FIG. 3 shows a drawing of the ground floor bases with bulkheads.

in FIG. 4 (placed in the abstract) shows a drawing of the ZZ assembled with a section of the vacuum tube.

ЗЗ (FIG. 1) contains: 1 - semi-base of ЗЗ made of non-magnetic material, 2 - bulkheads.

ЗЗ (FIG. 2) contains: 1 - semi-base of ЗЗ made of non-magnetic material, 2 - bulkheads, 3 - solenoid sections wound with copper wire.

ЗЗ (FIG. 3) contains: 1 - semi-base of ЗЗ made of non-magnetic material, 2 - bulkheads.

ЗЗ (FIG. 4) contains: 1 - semi-base of ЗЗ made of non-magnetic material, 2 - bulkheads, 3 - solenoid sections wound with copper wire, 4 - super-high vacuum tube for atomic and oncoming laser beams, 5 - atomic beam input (laser output beam), 6 - input of the laser beam (output of the atomic beam).

In this case, the center of the entrance of the laser beam 6 coincides with the exit of the atomic beam 5, as well as with the 3Z axis, and the parts of the solenoid 3 are connected to the half-bases 1, so that the resulting field of the solenoid 3 is directed collinearly or coincides with the line between the entrance of the laser beam 6 and the entrance of the atomic beam 5 , half-bases 1 with bulkheads 2 are connected with the help of sections of solenoid 3 into a whole ZZ around the vacuum tube 4.

Semi-base 1 with bulkheads 2 can be made of non-magnetic material such as VT-1, as well as aluminum alloys AMG-6, -5, solenoid 3 from enameled wire PETV-2 (d = 1 mm).

где k - волновой вектор, Г - ширина линии охлаждающего перехода, m - масса атома.The device works as follows, the atoms, falling into the zone of an inhomogeneous magnetic field, begin to decelerate with some acceleration due to scattering under the action of a counterpropagating laser beam. The upper limit for this acceleration is

where k is the wave vector, Г is the line width of the cooling transition, and m is the mass of the atom.

где v₀ - скорость атомов на входе ЗЗ, z - положение атомов,

- расстояние замедления (расстояние на котором скорость атомов v₀ снижается до некоторого заданного значения). Допплеровский сдвиг, возникающий в данном процессе, должен быть скомпенсирован Зеемановским сдвигом от магнитного поля. Профиль неоднородного магнитного поля, соответствующий условию замедления атомов описывается выражением

In this case, the velocity of atoms at the entrance of the ZZ and at a certain distance from the entrance is described by the expression

where v ₀ is the velocity of the atoms at the entrance of the ЗЗ, z is the position of the atoms,

- the deceleration distance (the distance at which the velocity of the atoms v ₀ decreases to a certain specified value). The Doppler shift arising in this process must be compensated for by the Zeeman shift from the magnetic field. The profile of an inhomogeneous magnetic field corresponding to the condition for the deceleration of atoms is described by the expression

где μ0 - магнитная постоянная, I - сила тока в витках соленоида, R - радиус витка с током, z - расстояние от центра витка с током до расчетной точки.In the case of a ZZ coil with a wire, the corresponding field can be obtained using the method of superposition of the magnetic fields of individual turns of the ZZ coil. The field along the axis of the loop with current is described by the expression

where μ0 is the magnetic constant, I is the current in the turns of the solenoid, R is the radius of the turn with current, z is the distance from the center of the turn with the current to the calculated point.

где М - общее количество слоев намотки соленоида, L - количество элементарных витков в слое намотки соленоида ЗЗ.An inhomogeneous magnetic field along the ZZ axis is the sum of the contributions of each element (loop with current), which are located in certain positions and placed around the ZZ axis,

where M is the total number of layers of winding of the solenoid, L is the number of elementary turns in the layer of winding of the solenoid ЗЗ.

Thus, by rotating the half-bases with bulkheads and simultaneously winding a copper wire on a vacuum tube, it is possible to place a solenoid with a ZZ current without disturbing the ultrahigh vacuum of the system, reducing the time spent and increasing the ability to adjust the magnetic field inhomogeneity of the Zeeman moderator.

Claims (1)

Atomic beam Zeeman moderator, which includes an ultrahigh vacuum tube with atomic and counterpropagating laser beams directed along its axis and a block for forming an inhomogeneous magnetic field profile fixed on the tube, characterized in that the forming unit consists of split half-bases with bulkheads, the planes of which are perpendicular to the axis of an atomic beam, while the split half-bases with bulkheads are made of non-magnetic material, between the bulkheads, by rotating the half-bases around the vacuum tube, sections of the solenoid are wound to provide the necessary gradient and direction of the magnetic field, while the step of placing the bulkheads is determined by the length of the sections of the rectangular section of the block solenoid winding forming the profile of the magnetic field, which connect the half-bases into a complete moderator structure.

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