DE8911237U1 - Sensor for measuring magnetic flux - Google Patents

Description

Julien Nuclear Research Facility Limited liability company

Description Sensor for measuring magnetic flux

The invention relates to a sensor for measuring magnetic flux, consisting of a superconducting ring with an incorporated Josephson element which _is coupled to an electrical oscillating circuit.

In such sensors, the superconducting ring with incorporated Josephson element is manufactured using thin-film technology, whereby the ring and Josephson element are applied by vapor deposition or cathode sputtering as a thin layer on a substrate that has the lowest possible dielectric losses.

To operate these known sensors, they are generally connected to an electrical parallel

/"·» oscillating circuit, hereinafter referred to as tank circuit, which

can also be superconducting, with resonance frequency f, into which a high-frequency current with the same frequency f is impressed. The superconducting ring dampens the tank circuit, whereby the magnitude of the damping depends on the magnetic flux through the superconducting ring. This changes the voltage drop across the tank circuit, which is used to read the sensor.

It is also known that the inherent noise of these sensors and thus their maximum sensitivity

PT 1.0982 GM

ba/stu

can be increased if the operating frequency of the tank circuit is increased. However, at higher frequencies (f > 500 MHz), the realization of TsnV circuits from discrete components, such as coils and capacitors, presents difficulties, and the coupling between the tank circuit and the superconducting ring also drops to too low values due to the inductance of the tank circuit coil decreasing with increasing frequency.

It is the object of the invention to provide a sensor

' , which will be available at a higher frequency than the

known sensors of this type can be operated with at least equally good coupling between the tank circuit and the superconducting ring containing the Josephson element.

This object is achieved according to the invention by a sensor having the features of claim 1,

In the sensor according to the invention, the superconducting ring and tank circuit are one component. This consists of the strip resistor, whereby the strip resistor

Q itself the tank circle and the limitation of the opening

the superconducting ring in which the Josephson element is incorporated. The superconducting ring is thus only formed during operation of the sensor ai:s.

Because the Josephson element is arranged along the longitudinal axis of the strip resonator, the current required for measuring the magnetic fluxes flows through it - provided a sufficiently high high-frequency current is fed in.

For the operation of the sensor, the resonance,

frequency that forms standing waves in the strip resonator. This can be done - if the strip resonator is initially of any length - by finding or setting the resonance frequency. However, if a specific frequency is to be used, the strip resonator must be designed so that its electrical length 1 corresponds to an odd multiple of the half-wave length of the operating frequency.

In order to place the superconducting ring with incorporated Josephson element as favorably as possible in the strip resonator, it is arranged diagonally at a point of maximum current flow in the strip resonator.

It is also advisable for a good coupling of the strip resonator to the room temperature electronics required for the operation of the sensor that the additional piece of strip line intended for this coupling is arranged near a voltage belly that forms in the strip resonator.

The version of the sensor according to the invention described so far is suitable for measuring the change in a magnetic flux in the same way as previously known sensors of this type - although with greater sensitivity. These are not usually absolute measurements. Rather, sensors of this type only detect a change in the magnetic flux, either by moving the sensor or by changing the magnetic field |. A homogeneous magnetic ^{field in the measuring range.}

field can then be recognized by the fact that it does not allow any relative change in the magnetic flux to be measured.

If, on the other hand, one wants to detect an inhomogeneous magnetic flux at the location of the sensor and thereby eliminate the influence of a superimposed homogeneous magnetic flux, which can, for example, arise from sources of interference located nearby, then a version of the sensor according to the invention is advantageous in which openings arranged one behind the other along the central or longitudinal axis of the strip resonator with a Josephson element located between them are provided, whereby the strip resonator is designed to be asymmetrical in the area of the openings both in relation to the openings and in relation to its central or longitudinal axis.

The asymmetry of the strip resonator in the area of the openings serves to generate a high-frequency current in the Josephson element. This can be achieved, for example, by having a lateral recess in one of the openings and thus a constriction at this point. The resulting current flow in this constriction in the strip resonator is different from that at the corresponding point near the other opening, i.e. the current distribution along the two openings is different. This leads to a resulting current through the Josephson element.

This also makes it possible to detect an inhomogeneous magnetic flux or magnetic field in the area of the two openings.

to recognize or measure a magnetic flux that changes differently in this measuring range in relation to the two openings, for example in the case of changing brain waves.

Embodiments of this second version of the sensor according to the invention comprise the features of claims B to 9.

A further embodiment of the sensor according to the invention consists in the fact that in a Josephson element designed as a '..' microbridge, the

Part of the substrate beneath the Josephson element is made of a material with the lowest possible thermal conductivity. This means that the critical current of the Josephson element can be reduced to more favourable values by the heat generated in the Josephson element through dissipation if the period of the operating frequency of the sensor is small compared to the time in which the heat generated in the Josephson element can be transported away through thermal conduction.

The two versions of the sensor according to the invention are shown schematically in the drawing and explained in more detail below:

Show it

Figure 1 the version of the sensor with a

Opening;
Figure 2 the version of the sensor with two

Openings.

The simple version of the sensor shown in Figure 1 consists of the strip resonator 1,

itta » · · ·

opening 2 integrated therein with the superconducting ring surrounding it. This superconducting ring is not shown in the drawing, since it only forms during operation as the ring current surrounding the opening. This ring current flows through the Josephson element 3, which is arranged along the central axis of the strip resonator 1, whereby care is taken that the part of the strip resonator opposite the Josephson element is wider than the Josephson element.

The additional strip 4 arranged parallel to the strip resonator 1 serves for the capacitive coupling of the strip resonator to an evaluation electronics not shown in the drawing.

The length 1 of the strip resonator is dimensioned so that it corresponds to an odd multiple of half the wavelength of the operating frequency. The Josephson element is arranged at a point of maximum current flow in the strip resonator 1.

The sensor version shown in Figure 2 consists of the strip resonator 1, two openings 2a and 2b integrated therein with a Josephson element 3 in between, and the further strip 4.

Near the opening 2b, the strip resonator 1 has a recess 5, so that it is thus asymmetrical both in relation to the openings and in relation to its central or longitudinal axis. As explained above, this version of the sensor is suitable for measuring inhomogeneous magnetic fluxes.

Claims (10)

Nuclear Research Facility Jiilich Limited Liability Company Protection Claims 1. Sensor for measuring magnetic flux, consisting of a superconducting ring with an incorporated Josephson element, which is coupled to an electrical oscillating circuit, characterized in that the electrical oscillating circuit consists of a piece of strip line (1) forming a resonator for standing electrical waves, in which there is an opening (2) provided for the magnetic flux to be measured with an adjacent Josephson element (3), so that the superconducting ring is integrated into the strip resonator (1), the Josephson element being arranged lying along the central or longitudinal axis of the strip resonator and that a further piece of strip line (4) adjacent to the strip resonator is provided for the capacitive coupling of the strip resonator (1) to an evaluation electronics. 2. Sensor according to claim 1, characterized in that the electrical length l of the strip resonator (1) corresponds to an odd multiple of half the wavelength of the operating frequency. 3. Sensor according to claim 1 or 2, characterized in that the Josephson element (3) is arranged at a point of maximum current flow in the strip transducer (1). PT 1 .0982 GM
I) a / st &ugr; 4. Sensor according to claim 1 to 3, characterized in that the further piece of strip line (4) is arranged in the vicinity of a voltage antinode forming in the strip resonator (1). 5. Sensor for measuring magnetic _flux consisting of a superconducting ring with an incorporated Josephson element, which is coupled to an electrical oscillating circuit. characterized. v' that the electrical oscillating circuit consists of one, a Resonator for standing electrical waves consists of a piece of strip line (1) in which two identical openings (2a, 2b) arranged one behind the other along the central or longitudinal axis of the strip resonator (1) are provided for measuring inhomogeneous magnetic fluxes, with a Josephson element (3) located between them, so that the respective superconducting ring is integrated in the strip resonator (1), that the strip resonator in the area of the openings both in relation to the openings and in relation to its central or longitudinal axis. / longitudinal axis is asymmetrical and that for the capacitive coupling of the strip resonator (1) to an evaluation electronics, a further piece of strip line (4) is provided adjacent to the strip resonator. 6. Sensor according to claim 5, characterized in that the openings (2a, 2b) are arranged symmetrically to the central or longitudinal axis of the strip resonator (1) I · · t I I f t I I · · 7. Sensor according to claim 5 or 6, characterized in that the electrical length l of the strip resonance,">rs (1) corresponds to an odd multiple of half the wavelength of the operating frequency. 8. Sensor according to claim 5 to 7, characterized in that the Josephson element (3) is anchored at a point of maximum current flow in the strip resonator (1). 9. Sensu:, according to claims 5 to 8, characterized in that the further disturbing strip line (4) is arranged in the vicinity of a voltage antinode forming in the strip resonator (1). 10. Sensor according to one of the preceding claims, characterized in that in the case of a Josephson element (3) designed as a microbridge, the part of the substrate below the Josephson element is made of a material with , with as little heat conduction as possible. suffered · · * ·