RU2693551C1 - Atomic beam zeeman retarder - Google Patents

Abstract

FIELD: physics.

SUBSTANCE: invention relates to quantum electronics, to devices for generation of inhomogeneous profile of magnetic field. Atomic beam Zeeman retarder (ZR) comprises atomic beam source and nonuniform field shaping unit arranged along atomic beam propagation axis. ZR also includes in-series connected source of counter optical radiation and source of thermal atomic beam. Proposed device comprises detachable frame made from nonmagnetic material with its blades accommodating matrixes made of permanent magnets, which are connected by end connectors in two halves of ZR, while halves of ZR are connected in their turn by end connectors around ZR vacuum pipe.

EFFECT: technical result consists in reduction of heat release and improvement of Zeeman retarder tuning.

1 cl, 4 dwg

Description

The present 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 the atomic beam (GZ) is based on the slowing down of the thermal atomic beam passing along the axis of the GZ by a counter laser beam. The deceleration efficiency is ensured by the degree of monotonicity of the inhomogeneous magnetic field and the effect of a laser beam that is opposed to the atomic beam, which leads to the compensation of the Doppler shift by compensation by changing the Zeeman shift. Those. The profile of the resonant magnetic field along the ZZ should correspond to the Doppler shift gradient.

There are two ways to obtain a resonant profile of a magnetic field: - using a coil with a current, - using permanent magnets.

The first method uses a simple-to-implement metal coil made from a wire with a current that is wound on a ZZ pipe, and which, along with the magnetic field, has a fairly large power consumption and heat release, which does not meet the requirements of modern atomic spectroscopy technology and atomic beam frequency standards In which, to reduce frequency uncertainty, there is a tendency to reduce heat generation surrounding the atomic cloud of parts (33, windows and walls of the vacuum chamber). The coils have a number of turns from 600-700 and more, which are wound on the pipe ZZ on a special profile of the longitudinal section with exact adherence to the position of the coils. When an electric current is passed through it, thermal power is emitted over 25–30 W, which leads to an increase in the temperature of the portion of the vacuum system surrounding the atoms, which in turn leads to a shift of the hourly resonance to the atomic beam frequency standards.

The second method is based on the placement of permanent magnets around the pipe ZZ. In this case, heat dissipation is absent. But there is a need to place magnets on a special profile. An important advantage of using permanent magnets is that there is no power consumption and heat dissipation. At low heat generation, there is no overheating of the vacuum system section, which does not lead to a shift of the hourly resonance in the optical frequency standards and an improvement in the metrological characteristics of the standards, namely, a partial improvement in the standards uncertainty.

Due to the discreteness of the magnets, a special frame is needed in which the magnets are placed. And because of the uncertainty of the magnetic moment of the magnets from batch to batch, an easily modifiable framework is needed, with the help of which one can build the required profile of the non-uniform field of the ЗЗ.

Known ZZ (Patent number: US 5,014,032, Date of Patent: 14 Apr. 1989), containing a set of rings of glued permanent magnets, which are two ring structures located along the vacuum tube, having radial and oppositely directed magnetization. Ring structures provide the resulting inhomogeneous in magnitude magnetic longitudinal field on the axis.

However, in the specified ZZ, the bonding of magnets of each individual ring is used, the gluing of rings also entails the impossibility of modifying the magnetic field profile on the axis, and it is not possible to change the number of permanent magnets or rings without removing the ZZ placement area from the vacuum system.

In addition, it is known the DZ (Patent No: US 8,710,428 B1, Date of Patent: Apr. 29, 2014), which is the prototype of the present invention and contains four cutout permanent magnets located symmetrically parallel to the axis of the ZZ, and located inside the vacuum tube, the axis of non-uniform the magnetic field coincides geometrically with the axis of one of the slowing laser beams; in addition to the main slowing beam, through a system of mirrors located in a vacuum tube, two radial biasing beams are connected through the system of mirrors at the output of the ЗЗ.

However, in the specified device, the placement of ZZ magnets inside the vacuum tube is used, and also four permanent magnets are made by cutting on a special profile from a single larger permanent magnet. That provides increased complexity of restructuring or optimization, modifying the profile of the magnetic field on the axis, and there is no possibility to change the number of permanent magnets or rings without removing the section of the location of the discharge zone from the vacuum system.

The task of the invention is to reduce heat generation and increase the possibility of setting the Zeeman moderator.

The task is achieved by the fact that in the known device Zeeman moderator atomic beam containing, located along the axis of propagation of the atomic beam, the source of the atomic beam and the block forming a non-uniform magnetic field profile, as well as consistently included source of oncoming optical radiation, which consists in an end connector is introduced; a blade with permanent magnets, in addition, a detachable frame made of a non-magnetic material, in the blades of which there are matrices of permanent magnets, which are connected by end connectors in two halves of the ЗЗ, and halves of ЗЗ, in turn, are connected by end connectors around the vacuum pipe ЗЗ.

The invention is illustrated by drawings. FIG. 1 shows a drawing of the end connector of the blades of the CZ, in FIG. 2 shows a drawing of a ZZ blade with a matrix of permanent magnets; FIG. W is a drawing of the assembly half ZZ with the mutual placement of the blades and the end connectors; FIG. 4 (placed in the essay) is a drawing of the DZ assembled with the section of the vacuum tube.

ZZ (Fig. 1) contains: 1 - end connector for blades and halves of ZZ from non-magnetic material.

ZZ (Fig. 2) contains: 2 - a matrix of permanent magnets, 3 - part of the frame to accommodate the matrix of permanent magnets (blade),

ZZ (Fig. 3) contains: 1 - end connector for blades and halves of ZZ from non-magnetic material, 2 - matrix of permanent magnets, 3 - part of the frame for accommodating the matrix of permanent magnets (blade), 4 - half of ZZ complete.

ZZ (Fig. 4) contains: 1 - end connector for blades and halves of ZZ from non-magnetic material, 2 - matrix of permanent magnets, 3 - part of the frame for accommodating the matrix of permanent magnets (blade), 4 - half of ZZ complete, 5 - vacuum a tube for atomic and counter beam laser beams, 6 is an atomic beam input (laser beam output), 7 is a laser beam input (atomic beam output).

The center of entry of the laser beam 7 coincides with the output of the atomic beam 7, as well as the axis of the ЗЗ, and the matrix of permanent magnets 2 is connected to the inside of the blade 3, so that the resulting field of the magnets 2 is collinear with the input line of the laser beam 7 - input atomic beam 6, a group of blades 3 with the help of end connectors 1 are connected in half ZZ 4, half Z 3 4 are united around the pipe ЗЗ 7 with end connectors 1.

The end connector 1 can be made of non-magnetic material such as birch or pine plywood, as well as aluminum alloys, the matrix of magnets 2 is made in the form of an assembly of permanent magnets, for example, from the NdFeB pseudo-alloy (Nd-iron-boron) of type N38-N50, the blade 3 can be made of non-magnetic material such as birch or pine plywood, as well as aluminum alloys, pipe 5 can be made of titanium or stainless alloys.

где k - волновой вектор, Г - ширина линии охлаждающего перехода, m - масса атома.The device works as follows, the atoms, entering the zone of a non-uniform magnetic field, begin to slow down with some acceleration due to scattering when exposed to a counter laser beam. The upper limit for this acceleration is

where k is the wave vector, G is the width of the cooling transition line, 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

At the same time, the speed of the atoms at the input of the ЗЗ and at some distance from the input is described by the expression

where v ₀ is the speed of atoms at the input of the WZ, 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 given value). The Doppler shift arising in this process must be compensated for by the Zeeman shift from the magnetic field. The profile of a non-uniform magnetic field corresponding to the condition of slowing down atoms is described by the expression

где μ0 - магнитная постоянная, М0 - магнитный момент одного элемента (магнита), (х, у, z) - координаты магнита.In the case of the permanent magnets, the corresponding field can be obtained by applying the method of superposition of the magnetic fields of the individual ЗЗ magnets. The field along the axis at a certain distance from the magnet is described by the expression

where μ0 is the magnetic constant, M0 is the magnetic moment of one element (magnet), (x, y, z) are the coordinates of the magnet.

где N - общее количество магнитов в матрице ЗЗ, G - общее количество матриц магнитов в лопастях ЗЗ.A non-uniform magnetic field along the axis of the ЗЗ is the sum of the contributions of each element (magnet), which are located in certain positions in the matrix and are placed around the axis of the ЗЗ,

where N is the total number of magnets in the ZZ matrix, G is the total number of magnet matrices in the ZZ blades.

Thus, through the use of permanent magnets placed by matrices in blades made of non-magnetic material, the number of which can vary from 0 to G (provided for by the design) and the possibility of removing the protective device from the pipe of the vacuum system, by using permanent magnets, energy consumption and heat generation are reduced and adjusting the inhomogeneity of the magnetic field of the Zeeman moderator; changing the number of blades with magnet arrays.

Claims (1)

The Zeeman (ZZ) moderator of an atomic beam containing an atomic beam source and a unit for forming a non-uniform magnetic field along the axis of the atomic beam propagation, as well as a series-connected source of opposing optical radiation and a source of thermal beam of atoms, characterized by non-magnetic material, in the blades of which are placed the matrix of permanent magnets, which are connected by end connectors in two halves of the ZZ, and halves of the ZZ, in turn, soy ineny end around a vacuum tube connectors PO.

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