RU2726851C1 - Frequency standard quantum hydrogen generator - Google Patents

Abstract

FIELD: hydrogen generators.SUBSTANCE: invention relates to a hydrogen generator and can be used in quantum hydrogen generators and quantum discriminators of frequency standards. Quantum hydrogen generator includes a resonator placed in a vacuum cap with a storage bulb connected to a source of hydrogen atoms by a vacuum line, in which there is a device for double magnetic sorting of states of hydrogen atoms, which includes a solenoid located in a magnetic screen, a hydrogen atom beam arranged between the first and second sorting magnets, arranged along the axis of propagation. Inside solenoid carcass there are two coils for creation of transverse alternating magnetic field, installed perpendicular to propagation axis of hydrogen atom beam, solenoid is made with variable winding turns its winding, wherein number of coils of solenoid along length varies according to ratio N=N×e, where Nis number of solenoid turns at point with coordinate z; Nis initial number of turns; z is a longitudinal coordinate; L is solenoid length.EFFECT: high efficiency of using a beam of hydrogen atoms to increase the output power of the hydrogen generator.4 cl, 4 dwg

Description

The invention relates to the field of quantum hydrogen generators (masers) of frequency standards and can be used in the development of quantum hydrogen generators and quantum discriminators.

An important task in the design of quantum hydrogen (H) masers is to increase the output power of its signal and frequency stability, which can be increased by using a system of double magnetic sorting of states of hydrogen atoms to obtain a beam of atoms in one quantum state.

In the classical design of a hydrogen frequency standard, for example, of the VCH-1003A type (developed by Vremya-Ch JSC), hydrogen atoms in two quantum states enter the storage flask of the quantum generator of the standard: F = 1, m _F = 0 and F = 1, m _F = + 1. Hydrogen atoms in the second state do not participate in the generation of generation, but participate in spin-exchange interactions with working atoms. The latter leads to an additional broadening of the spectral line and restriction of the increase in the lasing power with an increase in the beam intensity, which prevents an increase in the frequency stability of the hydrogen generator.

As the closest analogue of the proposed technical solution, a method of implementing a system of double magnetic sorting of states of hydrogen atoms (patent for invention RU No. 2692000) for quantum hydrogen frequency standards of the active type by the method of counter fields is adopted, in which the scattered field is measured by sorting magnets without a screen and with a screen on ; the shielding system from the external field is checked; preliminary assembly and installation of the sorting system in the lower vacuum chamber of the hydrogen generator; the area where the output power is most sensitive to changes in current is determined and the current configuration is established at which the output power is maximum.

The main difficulty in obtaining the required beam of hydrogen atoms (especially with a strict limitation of the length of the entire sorting system and the presence of stray fields of the sorting magnets) lies in the practical creation of a strictly defined configuration of magnetic fields that is resistant to changes in external conditions to achieve the highest probability of an inversion transition of hydrogen atoms. The disadvantage of this method of implementing the system of double magnetic sorting of the states of hydrogen atoms is the fact that such a system is sensitive to changes in external magnetic fields and requires complex adjustment of the strength of currents in the compensating coils, therefore, when implementing it, it is not possible to obtain positive results.

The technical objective of the invention is to increase the output power and increase the frequency stability of commercially available hydrogen generators and frequency standards based on them.

The essence of the technical solution to the problem lies in the fact that a quantum hydrogen generator containing a resonator with a storage flask placed in a vacuum cap, connected to a source of a beam of hydrogen atoms by a vacuum line, in which a system of double magnetic sorting of states of hydrogen atoms is located, including the first and second sorting magnets, according to According to the invention, between the sorting magnets in the magnetic screen there is a solenoid installed along the axis of propagation of the beam of atoms, inside the solenoid frame there are two coils to create a transverse variable magnetic field, mounted perpendicular to the axis of propagation of the beam of hydrogen atoms, the solenoid is made with a variable density of turns of its winding to create a certain gradient magnetic field along the beam axis, while the number of turns of the solenoid along the length varies according to the ratio: N _z = N ₀ × e ^{(2z / L + 1)} , where N _z is the number of turns of the solenoid at a point with coordinate z; N ₀ - the initial number of turns; z - longitudinal coordinate; L is the length of the solenoid, e is the base of the natural logarithm.

In embodiments of the device, the coils for creating an alternating magnetic field are located in the center of the solenoid frame, which reduces the influence of magnetic field inhomogeneities at the edge of the solenoid, and the implementation of the solenoid frame with a radius variable along the length allows the density of turns to be more evenly distributed along the length of the frame.

The technical solution is illustrated by drawings, which shows:

in fig. 1 is a general diagram of a hydrogen maser (generator) device;

in fig. 2 - device for double sorting of states of hydrogen atoms;

in fig. 3 - graph for determining the number of turns of the solenoid;

in fig. 4 is a schematic representation of the operation of a magnetic double sorting device for atoms.

The quantum hydrogen generator contains (Fig. 1) placed in a vacuum cap 1 microwave resonator 2 with a storage flask 3 connected to a source of a beam of hydrogen atoms 4 by a vacuum line 5, in which there is a device for double magnetic sorting of states of hydrogen atoms 6 (Fig. 2), including a solenoid of variable radius 8 located in the magnetic screen 7, mounted (oriented) along the propagation axis of the beam of hydrogen atoms, inside (in the center) of the frame of solenoid 8 there are two coils 9 and 10 for creating an alternating magnetic field, installed (oriented) perpendicular to the axis of propagation of the beam of hydrogen atoms between the first 11 and the second 12 sorting magnets. The solenoid (40 mm long) is made on a sectioned frame with a variable density of turns of its winding (different number of turns in the frame sections), while the number of turns of the solenoid along the length varies according to the numerical N _z = N ₀ × e ^{(2z / L + 1)} , where N _z is the number of turns of the solenoid at a point with coordinate z; N ₀ - the initial number of turns; z - longitudinal coordinate; L is the length of the solenoid, e is the base of the natural logarithm (Fig. 3). Solenoid 8 and coils 9 and 10 are powered from the control unit (not shown in the figures).

The work of a hydrogen quantum generator of a frequency standard is as follows. A beam of hydrogen atoms escapes from a source of atomic hydrogen 4 into a storage flask 3 located inside a cavity resonator 2 tuned to a frequency corresponding to the frequency of transition of hydrogen atoms from the excited state to the ground state. The resonator creates the feedback necessary for self-excitation of the generator, which begins to work by emitting electromagnetic waves of a stable frequency. The difficulty in obtaining a beam of hydrogen atoms in one quantum state (especially when the length of the entire sorting system of the generator is strictly limited and the presence of stray fields of the sorting magnets 11 and 12) lies in the practical creation of a certain configuration of the magnetic field in the interaction region for the effective probability of the inversion transition of hydrogen atoms from the state F = 1, m _F = + 1 into the state F = 1, m _F = -1 (Fig. 4). The inversion region of the device consists of a solenoid 8, which should create a longitudinal magnetic field slowly varying along the axis of the atomic beam (and its intensity should increase linearly to a high degree, i.e., with a constant gradient), and a pair of coils 9 and 10 to create in the central part of the solenoid 8 of the transverse alternating (units of MHz) magnetic field. To ensure these conditions, the number of turns of the solenoid along the length must change according to the ratio N _z = N ₀ × e ^{(2z / L + 1)} , which was found using numerical methods. By setting the length L of the solenoid and the initial number of turns N _{0 of the} solenoid winding, we determine the number of turns N _{z of the} solenoid at a point with coordinate z and along the entire length of the solenoid (Fig. 3).

The interaction of the magnetic moment of the hydrogen atom with the superposition of these fields (Fig. 4) leads to a reorientation of the projection of the magnetic moment of the atom to the direction of the external field from F = 1, m _F = + 1 to F = 1, m _F = -1. Then the atoms are sorted out by the second magnet 12 and only atoms in the state F = 1, m _F = 0 enter the storage flask 3. The proposed device is significantly more resistant to the disturbing effects of external fields.

According to the performed estimates, the decrease in the limiting frequency instability of the hydrogen frequency standard due to the exclusion of atoms in the state with F = 1, m _F = + 1 can reach 1.6 times. As a result of the experimental studies, a decrease in the frequency instability by 1.5 times was obtained in comparison with the industrially produced hydrogen frequency standards.

Claims (4)

1. Quantum hydrogen frequency standard generator containing a resonator placed in a vacuum bell with a storage flask connected to a source of a beam of hydrogen atoms by a vacuum line, in which a system of double magnetic sorting of states of hydrogen atoms is located, including the first and second sorting magnets, characterized in that between the sorting magnets in the magnetic screen there is a solenoid installed along the axis of propagation of the beam of atoms, inside the frame of the solenoid there are two coils for creating a transverse variable magnetic field, installed perpendicular to the axis of propagation of the beam of hydrogen atoms, the solenoid is made with a variable density of turns of its winding to create a certain gradient of the magnetic field along beam axis, while the number of turns of the solenoid along the length varies according to the ratio: N _z = N ₀ × e ^{(2z / L + 1)} , where N _z is the number of turns of the solenoid at a point with coordinate z; N ₀ - the initial number of turns; z - longitudinal coordinate; L is the length of the solenoid, e is the base of the natural logarithm. 2. The quantum hydrogen generator according to claim 1, characterized in that the transverse magnetic field coils are located in the center of the solenoid frame. 3. The quantum hydrogen generator according to claim 1, characterized in that the solenoid frame is made with a radius variable along its length. 4. The quantum hydrogen generator according to claim 3, wherein the solenoid frame is sectioned.

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