DE19717801A1 - Coupling arrangement for rf SQUID magnetometer - Google Patents

Abstract

The coupling arrangement includes a base plate which is provided as an outer loop (10a) coplanar to a rf SQUID (2) and a tank oscillation circuit (1). The oscillation circuit encloses an inner loop. Both loops are provided with a slit, whose relative position in the inner and outer loops determine the resonance frequency. A flux transformer can be formed within the tank oscillation circuit, provided by the coplanar outer loop, the inner loop and a capacitor (3).

Description

The present invention relates to an arrangement for coupling an rf-SQUID to a superconducting tank resonant circuit and to a base plate in which the tank resonant circuit and the rf-SQUID a coplanar structure bil and the tank circuit has a slot.

Various proposals have been followed so far rf-SQUID magnetometer to be attached to superconducting tank resonant circuits couple.

One possibility is to ver a λ resonator to which an rf-SQUID is galvanically coupled and which also works as a flow pickup loop. A Such a SQUID magnetometer can have a tank frequency of 3 GHz to have.

However, the use of a λ resonator is problematic table, since this is only a low quality of some 100 shows. In view of the already with the λ / 2-Re Sonators achieved grades of several thousand quite a small size. Furthermore, the fact that due to the galvanic coupling a difficult to calculate render parameters, namely the high frequency current distribution, with considerable problems. The high frequency current distribution does not make it easy Size to be calculated or controlled experimentally The SQUID layout is therefore difficult to optimize.

Another option is to use planar LC oscillation circles made of YBaCuO thin layers with high frequency and high quality. These LC resonant circuits are in a flip-chip arrangement with the rf-SQUID in washer-SQUID structure operated. The resulting parasitic  capacities between the LC resonant circuit and the rf-SQUID reduce the quality of the LC resonant circuit and make the current distribution in the combined LC resonant circuit / wa sher-SQUID structure complicated.

In the as yet unpublished application 196 11 900.6 the applicant described the arrangement mentioned in the introduction. This solves the problem of parasitic capacitances. After as before, there is the problem that due to the facts che that the coplanar rf-SQUID and tank resonant circuit not in one plane with the base plate can be arranged and the base plate also a poss Liche noise source represents the use of a rf-SQUID magnetometer can restrict.

The object of the present invention is therefore an order to create that when coupling an rf-SQUID-Mag netometers to a superconducting resonant circuit the above fixed problems.

The object is achieved according to claim 1 in that the base plate is designed as an outer loop coplanar with the rf-SQUID and the tank resonant circuit and has a slot, and in that the tank resonant circuit comprises an inner loop in which the slot is formed and the orientation the slots of the inner loop and the outer loop to each other determines the resonance frequency f _r .

The arrangement according to the invention relates to the poss possibility of an advantageous, optimal coupling of a rf-SQUID to a tank resonant circuit and a base plate, which does not have the disadvantages mentioned above. With the fully integrated arrangement of rf-SQUID, tank swing circle and base plate and training or orientation the slots in the rf-SQUID and in the base plate according to An saying 1, the tank frequency can be geo in a simple manner set depending on the metric and thus offers an essential Chen advantage z. B. when building a multi-channel SQUID system  tems for medical applications. Furthermore, can suppresses noise caused by the base plate will.

In addition, the fully integrated arrangement makes it easy che estimation of the coupling between the rf-SQUID and the Tank circuit.

According to claim 2, it is advantageous that an adjustment of the slots to each other causes a change in the resonance frequency f _r 300 ≦ Mhz.

Another advantage of claim 3 is that a Defined superconducting short circuit between the rf-SQUID and the tank circuit is installed. The resonance frequency of the resonant circuit namely decreases with decreasing Di mension to. Above a cut-off frequency of 1 GHz, the needed SQUID electronics but very complex and expensive. Due to the defined superconducting short circuit, the Resonance frequency significantly reduced, so that a very simple possibility results from simple geomes drive change discrete frequency ranges within a Range of 600 MHz, and always with very small dimensions still get resonance frequencies up to 500 Mhz. This discrete frequencies are for the realization of a more channel HTSL SQUID systems is a necessary requirement.

Further advantages of the present invention are achieved by receive the features of subclaims 4 to 11.

Embodiments of the present invention are described in the fol described in more detail with reference to the drawings. Show it:

Fig. 1a is a schematic view of a first geometry of a SQUID magnetometer with a base plate designed as a coplanar loop according to the first embodiment of the present invention;

FIG. 1b shows a schematic view of a second geometry of a SQUID magnetometer with a base plate designed as a coplanar loop according to the sten he embodiment of the present invention;

FIG. 1c is a schematic view of a third geometry of a SQUID magnetometer with a base plate designed as a coplanar loop according to the sten he embodiment of the present invention;

Fig. 2 is a diagram of a test measurement with a geometry according to Fig. 1a;

Fig. 3a is a schematic view of a SQUID mag netometer without a built-in short circuit;

Fig. 3b is a schematic view of a SQUID magnetic netometer according to a second embodiment of the present invention with built-in short circuit and with a first geometry;

Fig. 3c is a schematic view of a SQUID magnetic netometer according to a second embodiment of the present invention with built-in short circuit and with a second geometry;

Figure 3d is a schematic view of a SQUID mag netometer according to a second embodiment with built-in short circuit and with a third geometry.

FIGS. 4a and 4b is a schematic diagram of an rf-SQUID with a planar tank circuit and a base plate;

Fig. 5 is a schematic plan view of an rf-SQUID and a tank circuit without a coplanar base plate;

In Fig. 4a and 4b, a tank resonant circuit 1 and an rf-SQUID magnetometer 2 are shown with planar resonant circuits and λ / 2 or λ resonators, which are coupled to a base plate 10 made of metal or superconductor material. As a result, the tank resonant circuit 1 with integrated SQUID 2 and the base plate 10 cannot be arranged in one plane. In addition, the base plate 10 represents a possible source of noise, which can restrict the use of an rf-SQUID magnetometer 2 . FIG. 5 shows a tank resonant circuit 1 with a rf-SQUID magnetometer 2 arranged coplanarly without a base plate 10 .

In Fig. 1a to 1c, an inventive arrangement is shown in a first embodiment schematically, in which the base plate 10 is formed as a coplanar arrangement in the form of an outer loop 10 a. This allows the tank circuit 1 , the SQUID 2 and the base plate 10 to be arranged in one plane.

In Fig. 1a, 1b and 1c a different geometry of a SQUID magnetometer 2 is shown in each case which is present with a coplanar arrangement of an inner loop 1 a of the tank circuit 1 and the outer loop 10 a of the base plate 10 as a rf resonant circuit. Another external superconducting loop 10 a is added to the SQUID geometry in FIGS . 4 a, 4 b. This loop 10 a is provided with a slot 11 the coplanar resonant circuit. The area A in Fig. 1a, 1b, 1c may be used as washer-, multiloop or current injection SQUID structure may be designed. It is also possible to use this area as a flux concentrator or flux transformer in order to combine the coplanar resonant circuit with a washer SQUID magnetometer in flip-chip geometry.

A great advantage of these coplanar resonant circuits 10 a is the geometry-dependent resonance frequency of the resonant circuit. The only difference in the geometries shown in Figs. 1a to 1c is the orientation of the slot 11 in the outer loop to the slot 4 in the inner loop 1 a. In Fig. 1a, both slots 4 , 11 are aligned one above the other, the difference in orientation is 0 degrees or 360 degrees. The resonance frequency is f _r = 850 MHz. If you change the orientation to 180 degrees ( Fig. 1c), the resonance frequency decreases to f _r = 850 MHz. At 90 degrees ( Fig. 1b), the resonance frequency f _r = 650 MHz. This results in a very simple possibility of achieving discrete frequency ranges within a range of 300 MHz by simply changing the geometry. These discrete frequencies are a necessary prerequisite for the implementation of a multi-channel HTSL squid system.

A simple change in the geometry of the coplanar resonant circuit 10 a results in a change in the frequency of the tank frequency of the rf-SQUID 2 . This is a significant advantage over the prior art, especially with regard to the construction of a multi-channel SQUID system for medical applications, for example.

FIG. 2 shows test measurements with this layout which, at a resonant frequency of the tank resonant circuit of 850 MHz, have given a quality factor of approximately 5000 and a white noise of 1.85.10 ^-5 Φ _o / √Hz ( FIG. 2).

Figs. 3b to 3d show the geometry of a coplanar resonant circuit according to a second embodiment of the present invention with a defined supralei Tenden short. 5 In Fig. 3a the resonant circuit is shown without this short circuit 5 . The frequency in FIG. 3a is f _o = 1.1 GHz with a quality of Q ≧ 5000. Defined superconducting short circuits 5 are installed in FIGS . 3b to 3d. These short circuits 5 are attached at 180 degrees ( FIG. 3b), 90 degrees ( FIG. 3c) and 360 degrees ( FIG. 3d). The changes in the resonance frequency in FIGS . 3b to 3d with the short circuits 5 compared to the resonance frequency without a short circuit are considerable. In Fig. 3b the resonance frequency is f ₁ = 920 MHz, in Fig. 3c the resonance frequency is f ₂ = 803 MHz and in Fig. 3d is the resonance frequency f ₃ = 620 MHz. The quality is still better than Q ≧ 5000 for all resonance circuits manufactured. Since the quality determines the coupling between SQUID and resonance circuit, the SQUID function is not affected by the improvement presented here.

This results in the very simple possibility of achieving discrete frequency ranges within a span of 600 MHz by simply changing the geometry. Even with substrate dimensions of 10.10 mm ² , resonance frequencies of up to 500 MHz can be achieved by the invention.

Claims (13)

1. Arrangement for coupling an rf-SQUID to a supralei tend tank resonant circuit and to a base plate in which the tank resonant circuit and the rf-SQUID form a coplanar structure and the tank resonant circuit has a slot, characterized in that the base plate as an outer loop ( 10 a) is coplanar with the rf-SQUID ( 2 ) and the tank circuit ( 1 ) and has a slot ( 11 ), and that the tank circuit ( 1 ) comprises an inner loop ( 1 a) in which the slot ( 4 ) is formed and the orientation of the slots ( 4 ; 11 ) of the inner loop ( 1 a) and the outer loop ( 10 a) zueinan determines the resonance frequency f _r . 2. Arrangement according to claim 1, characterized in that an adjustment of the slots ( 4 , 11 ) causes a change in the resonance frequency f _r of less than or equal to 300 MHz. 3. Arrangement according to claim 1 or 2, characterized in that a defined superconducting short circuit ( 5 ) is installed between the rf-SQUID ( 2 ) and the tank resonant circuit ( 1 ). 4. Arrangement according to claim 3, characterized in that the defined superconducting short circuit ( 5 ) between the inner loop ( 1 a) and the outer loop ( 10 a) is built. 5. Arrangement according to claim 3 or 4, characterized in that the orientation of the short circuit ( 5 ) to the slot ( 4 ) of the inner loop ( 1 a) determines the resonance frequency f _r . 6. Arrangement according to one of claims 3 to 5, characterized in that the installation of the defined superconducting short circuit ( 5 ) causes a change in the resonance frequency f _r of less than or equal to 600 MHz. 7. Arrangement according to one of the preceding claims, characterized in that the rf-SQUID ( 2 ) has a SQUID with washer-SQUID structure. 8. Arrangement according to one of claims 1 to 6, characterized in that the rf-SQUID magnetometer ( 2 ) has a SQUID with multiloop SQUID structure ( 5 ). 9. Arrangement according to one of claims 1 to 6, characterized in that the rf-SQUID magnetometer ( 2 ) has a SQUID with current injection SQUID structure ( 6 ). 10. Arrangement according to one of claims 1 to 6, characterized in that the rf-SQUID magnetometer ( 2 ) has a SQUID with single-layer or multi-layer transformers ( 7 ) with several turns. 11. Arrangement according to one of claims 1 to 6, characterized in that the rf-SQUID magnetometer ( 2 ) has a SQUID with a double pel coil gradiometer ( 8 ). 12. The arrangement according to claim 9, characterized in that the double coil gradiometer ( 8 ) with two series-connected ge opposing coils ( 9 ) is formed. 13. Arrangement according to one of the preceding claims, characterized in that
that the tank resonant circuit ( 1 ) has dimensions of less than 10 × 10 mm ² .