DE4212028A1 - Grain boundary-based Josephson element - uses epitaxial deposition of ceramic superconducting material on surface contg. step in height with suitable slope angle - Google Patents

Abstract

The junction is made with ceramic oxide superconducting material deposited epitaxially on a substrate with a height step in its surface which produces grain boundaries at both upper and lower level. The feature is that the width of the superconducting material (3c) on the step (B) and (3b,13b) on the lower level (b1,b2) are much larger than that of the film (3a) on the upper surface (b1). This is pref. realised by defining 2 parallel structures (3,13) of which one (3) has a narrow track and the other a much wider track (13) which are connected together at least via the film on the slope (10). The width (b2) is pref. at least 3 times the width (b1). The angle of the slope with the horizontal planes is pref. at least 45 deg. At least one junction is used, with a slit, to form a SQUID device. USE/ADVANTAGE - The method to produce a grain boundary induced Josephson effect is more reliable and easier to control than currently available techniques. The effect operates only in the upper layer of the film and the effect can be avoided at the lower part of the slope by providing a large shunting area. The process allows SQUIDs to be constructed easily.

Description

The invention relates to a grain boundary Josephson element with metal oxide high-temperature superconductor (HTS) material on an epitaxial surface, the a step with a beveled edge between one grain boundary inducing upper edge and a grain boundary has inducing lower edge, wherein over the Step strip-shaped conductor pieces made of the HTS material extend with a predetermined width. Such a jo sephsonelement comes from the publication "IEEE Trans. Magn. ", Vol. 27, No. 2, March 1991, pages 3062 to 3065 forth. The invention further relates to a method for Production of such a Josephson element and its Use.

Superconducting metal oxide compounds with high jump temperatures T _c of in particular above 77 K, which can therefore be cooled with liquid nitrogen (LN ₂ ), are generally known. Corresponding metal oxide compounds, which are in particular cuprates, are based, for example, on a material system of the Mel-Me2-Cu-O type, the components Me1 containing a rare earth metal including Y and Me2 an alkaline earth metal at least. The main representative of this group is the four-component material system Y-Ba-Cu-O. In addition, phases of five- or higher-component cuprates such as z. B. based on the material system Bi-Sr-Ca-Cu-O or Tl-Ba-Ca-Cu-O also jump temperatures above 77 K.

We have succeeded using special PVD or CVD processes to produce thin layers from these HTS materials, which enable a high critical current density. One is therefore also strives with so-called layers Form Josephson elements or contacts, as ge nerell of the conventional metallic superconductor materials that are cooled with liquid helium (LHe), are known. However, this occurs in contrast to the conventional metallic superconductor materials Problem that the known metal oxide HTS Materials only a short coherence length and a strong one Have anisotropy.

Taking this problem into account, a way to an education of Josephson elements in a targeted Exploitation of grain boundaries between neighboring HTS crises seen stall areas. This is from observation assumed that grain boundaries are often used in the HTS material show known Josephson effect. One has therefore ver seeks through the targeted incorporation of crystal defects in a substrate, e.g. B. by installing a bicrystal Twin boundaries in the lattice structure of the substrate these flaws grain boundaries in one on it to generate different HTS layers (cf. e.g. "Phys. Rev. B ", Vol. 41, No. 7, March 1990, pages 4038 to 4049 or "Physica C", vol. 170, 1990, pages 315 to 318).

With Josephson, which can be found in EP-A-03 64 101 element takes advantage of the fact that thin films are made of  metal oxide HTS material with a vertical out direction of the c-crystal axes with respect to the film plane a sufficiently flat unevenness of a substrate surface che can grow away without interference, but with one Form grain boundaries there on steeper flanks. Accordingly, on a flat substrate in one Area where a Josephson element is to be created Crystal structure of the substrate in the form of disruptive material deposited in a burr-like survey. If now on egg In such a structure, an HTS thin film epitaxially grows, in this film the apex area of the a disturbance of the crystal structure in Form of a grain boundary, which because of its "weak Link "properties represents a Josephson contact such contact forms the basis of a so-called grain border-Josephson element.

Another way to train a grain limit-Josephson element is according to the mentioned EP-A seen in that a slightly abge in the substrate angled or beveled flank incorporated. If then one over the edge between the non-beveled part the substrate surface and the bevelled edge are blue fender HTS film is deposited, one observes this edge a disturbance of the grain boundary Crystal orientation of the film. According to EP-A, the bevelled edge, however, by a corresponding Ab grinding of the substrate are formed. Such one The process is very complex and hardly possible Provision of entire arrays of corresponding Josephson elements te.  

Furthermore, it is from the literature mentioned at the beginning from "IEEE Trans. Magn." known a grain boundary Joseph sonelement with an epitaxial HTS filmstrip on an egg a step-like transition between two levels of an epi to train a taxable document. The one between the waiter edge of the step and its lower edge extending over aisle area of the pad provides a beveled Flank, the surface of which passes the upper level included an acute angle (<90 °). To this In the HTS over this level Filmstrip formed two grain boundaries, namely on the Top edge of the step and on its bottom edge. It results such a series connection of two Josephson contacts. However, this is especially for training from SQUIDs disadvantageous. At the lower grain boundary, namely errors due to etching residues and impurities when incorporating the level into the epitaxial-capable Un in particular by means of an etching step, not easy to avoid. The yield in manufacturing corresponding Josephson elements and their reliability are affected accordingly.

The object of the present invention is the Josephson element with the characteristics mentioned above to design that the problems of the state of the Technology are at least reduced. In particular, that should Josephson element relatively easy with reproducible electrical properties. Also whole arrays or electrical arrangements such as SQUIDs in a simple manner let form.  

This object is achieved in that a middle, located on the flank between the upper steps te and the lower edge of the ladder section so like at least one on the bottom of the step this middle conductor piece adjacent conductor piece before seen, the width of which is greater than that before certain width of an upper, at the top of the step the middle conductor section of adjacent conductor section.

The ver with this configuration of the Josephson element tied advantages can be seen in particular in that only that grain boundary used as a Josephson contact that is at the top of the step by epitakti growth.

The one in at least one over the lower edge of the step leading strip-shaped conductor track (conductor strips) trained grain boundary is namely due to the inventions according to the broad design of the conductor pieces of this Conductor so widened that practically no we considerable limitation of the current carrying capacity, like this otherwise it is the case with Josephson contacts. The means works with the Josephson element according to the invention the grain boundary at the bottom of the step quasi as a su short circuit. The consequences of this are beneficial large tolerances regarding the depth of the stage, the Quality of the underlay on the lower level of the step, for defects at the lower grain boundary and with regard to the adjustment of a mask relative to the step, with which mask the geometry of the conductor pieces on the Flank and the lower level of the step is to be defined.  

Advantageous refinements of the Josephson element according to the invention result from the associated subclaims forth.

For the production of a corresponding Josephson element a method is particularly suitable in which the structure ration of the upper conductor piece by means of a beam takes place at an angle to the level of the conductor piece hits, which is at most as large as the inclination win is the flank opposite this plane. In particular can be made from an HTS film in an etching process using a Ion beam the conductor piece are structured. With egg Such directed ion etching remains unaffected the part of the HTS film. In this way, an etching can advantageously be carried out perform on a much rougher scale than it does Usually used to develop Josephson contacts is such.

The use of at least is particularly advantageous a Josephson element according to the invention for building a SQUIDs whose SQUID loop has a slot that is closed on the flank. In this way the part of the SQUID loop that closes the slot Avoiding grain boundaries.

To further explain the invention, reference is made below to the schematic drawing, in which FIG. 1 illustrates a Josephson element according to the invention. A method step for producing such a Josephson element is indicated in FIG. 2.

Fig. 3 shows a SQUID with two Joseph son elements according to the invention. In FIG. 4, an alternative Anschlußmög friendliness is shown for such a SQUID. In the figures, corresponding parts are provided with the same reference symbols.

The Jo sephsonelement shown in FIG. 1, generally designated 2 , has a thin film structure made of known superconducting materials with a high transition temperature T _c of in particular over 77 K. The composition of corresponding HTS materials is based on a metallic component and oxygen-containing material system. As an exemplary embodiment, the special material system Y-Ba-Cu-O is the HTS material YBa ₂ Cu ₃ O _7-x (with 0, 5 <· <1) selected. However, the material of the Josephson element according to the invention is not limited to this special material system; that is, other multicomponent oxide-ceramic HTS-Supralei termaterials are equally well suited, which are not attributable to this special material system and at least partially contain other and / or additional metallic components and oxygen.

The Josephson element 2 has a thin conductor strip, generally designated 3, from the selected HTS material. This conductor strip 3 is deposited epitaxially on egg ner layer 4 in a special way and is intended to ensure a high critical current carrying capacity (current density) of the order of at least 10 ⁴ A / cm ² in the vicinity of the transition temperature T _{c of} its HTS material. The thickness D of the conductor strip 3 is z. B. in the order of 1 nm to 500 nm.

The base 4 can in particular be formed by a substrate known per se, on which the HTS material can grow epitaxially according to known methods. Corresponding substrate materials, the respective crystalline unit cell advantageous to the corresponding dimen sions of the unit cell of the HTS material used to fit dimensions are, for. B. SrTiO ₃ , BaTiO ₃ , LaAlO ₃ , NdAlO ₃ , NdGaO ₃ , MgO, MgAl ₂ O ₄ or Y-stabilized ZrO ₂ . Also suitable as substrate Si, which can also be doped or as a Si compound, is suitable if it is generally covered with a diffusion-inhibiting intermediate layer, a so-called "buffer layer". For the exemplary embodiment, a SrTiO ₃ substrate is selected below as a base.

Since the substrate 4 is designed to be step-shaped, its surface to be provided with the structure according to the invention is divided into two surface parts 5 and 6 lying in different parallel planes E 1 and E 2 . The mutual distance between the two planes E 1 and E 2 is denoted by e. It is generally in the order of magnitude of 100 nm. The surface parts 5 and 6 form a common step 7 between . This in the substrate 4 z. B. etched step has an oblique edge 11 between an upper edge 9 and a lower edge 10 . This means that the normal N 1 on the plane E 1 (or E 2 ) should include a predetermined acute angle α (<90 °) with the normal N 2 on this flank. Over this level 7 , the Josephson element 2 he should stretch. Therefore, its conductor strip 3 is divided into two conductor pieces 3 a and 3 b separated by the stage, which lie in the two planes E 1 and E 2 , and a conductor piece 3 c on the flank 11 . The conductor strip should have a predetermined width b 1 transverse to the current carrying direction through the Josephson element 2 .

The width of the Josephson barrier of the element 2 according to the invention is defined by the width b 1 of the upper web or strip-shaped conductor piece 3 a, which lies in the plane E1 and leads to the upper edge 9 . This width b 1 should be less than the Josephson penetration depth dependent on the current density of the element and is therefore generally of the order of 1 μm. The height of the Josephson barrier of the element is correspondingly given by the thickness D of the conductor strip 3 in the area of the upper edge. The conductor strip 3 extending over the upper edge 9 there forms in a manner known per se (cf. EP-A mentioned) a grain boundary, the electrical properties of which are also determined by the size of the angle of inclination α of the flank 11 with respect to the plane E 1 . Angles of more than 30 °, preferably more than 45 ° and in particular more than 60 ° are regarded as favorable with regard to the formation of suitable grains. According to the invention, the effectiveness of the grain boundary formed on the lower edge 10 in the conductor strip 3 is suppressed by bridging it over a much greater width. Here too, not only is the width B of the (middle) conductor piece 3 c sensitive on the flank 11 chosen to be substantially larger than the width b 1 , but this middle conductor piece borders on the lower step edge 10 a further (lower) conductor piece 13 b, whose width b 2 is also we significantly larger than that of the upper conductor piece 3 a.

The conductor piece 13 b is part of a correspondingly wide conductor strip 13 . This conductor strip he stretches for reasons of simplified lithography not only over the bottom edge 10 , but over the entire step 7 parallel to the conductor strip 3 and is connected to this over the middle, on the flank 11 accordingly broadly designed conductor piece 3 c. The conductor strip 13 thus also contains an upper conductor piece 13 a of the width b 2 lying in the upper plane E 1 . In order to ensure the desired superconducting short-circuit at the lower edge of the stage 10 , the widths b 2 of the conductor piece 13 b and B of the conductor piece 3 c must each be several times, preferably at least three times wider than the width b 1 of the upper conductor piece 3 a. The width B is at least the width te b 1 greater than the width b 2 .

The different widths of the web-like conductor pieces 3 a, 3 b and 13 a, 13 b compared to the width B of the middle conductor piece 3 c can advantageously be achieved by directional exposure or by directional etching, in which the HTS layer on the Edge 11 remains. A corresponding method is indicated in the section shown in FIG. 2. An over the stage 7 of the sub strate 4 extending HTS film 15 is covered with a varnish 16 common for photolithographic processes. In order to structure an etching mask for the parts 15 a of the HTS film located on the upper surface part 5 of the substrate 4 from this lacquer, the lacquer is exposed to a light beam which is advantageously applied to the lacquer at the angle α of the slope of the flank 11 or hits at a slightly smaller angle. In this way, exposure of the flank is avoided. The part of the HTS film which is not covered by the resulting etching mask is subsequently subjected to an etching treatment in a known manner. Furthermore, the HTS film 15 can also advantageously be structured directly in the region of the upper surface part 5 by using an ion beam 17 under the win angle α aimed at the parts to be etched 15 a of the film. The part 15 b of the HTS film located on the edge 11 remains quasi in the shadow of the etching beam 17 and thus maintains its full width.

To structure the HTS film according to FIG. 2, other known methods can of course also be used. A method that is particularly suitable is that from the publication "Appl. Phys. Lett.", Vol. 55, No. 9, 28.08.1989, pages 896 to 898 or vol. 57, no. 23, 03.12.1990, pages 2504 to 2506. Accordingly, an auxiliary material preventing the arranged growth of the HTS material is applied at the locations on the substrate 4 as a structuring mask, where no area with the required superconducting properties is desired. By diffusion processes between the predetermined auxiliary material and the HTS material, the formation of an electrically conductive phase and in particular the crystal orientation required for good superconducting properties in the film 15 can be suppressed during the deposition of the film 15 . Suitable auxiliary materials here are, for example, Si or SiO ₂ or amorphous layers made of other known materials. In this method, the auxiliary material is also advantageously deposited at the predetermined angle α.

Furthermore, it is also possible, if necessary, to subsequently form a structuring mask from a corresponding auxiliary material on the already deposited HTS film 15 , with a deposition under the predetermined angle α likewise advantageously being carried out. The superconducting properties of the HTSL film 15 can then be destroyed by a suitable heat treatment in the areas in front of certain areas covered by the structuring mask due to diffusion processes between the auxiliary material and the HTS material.

The structuring methods indicated above, using an auxiliary material which prevents or destroys the superconducting properties of the HTS film 15 , have the particular advantage that a possibly damaging effect of a lifting or etching process of non-superconducting partial film surfaces is to be avoided and no lateral film edges arise from which z. B. could diffuse oxygen from the HTS film.

With Josephson elements 2 according to the invention, electronic circuit devices such as SQUIDs in particular can advantageously be constructed. A corresponding embodiment example shows not to scale Fig. 3 as a supervision. A direct current (DC) SQUID, generally designated 20 , which is to be produced according to known methods of thin-film technology, has a wide, ring-shaped loop 21 made of superconducting material with a rectangular or also a round outline. This loop is provided with a contact surface 22 , a so-called “contact pad” and interrupted on one side by a narrow gap or slot 23 . There the loop ends in two outwardly leading, narrow, web-like conductor strips 3 and 3 '. The axial length L of these strips is generally of the order of a few microns. In the outwardly leading area of the conductor strips 3 and 3 'there are two Josephson elements 2 and 2 ' which are characteristic of a DC-SQUID. These elements are each formed according to the invention as grain boundary Josephson elements on only one edge of a step 7 (see. Fig. 1). Correspondingly, each of the conductor strips 3 and 3 'leads over a step edge 9 indicated by a dotted line, an oblique flan ke over a correspondingly dotted step edge 10 away. Only the grain boundaries 24 and 24 'formed at the upper edge 9' according to the invention are intended to define the Jo sephson elements 2 and 2 '. Therefore, the SQUID loop 21 must be closed so that the grain boundaries formed at the bottom edge 10 25 or 25 'have no effectiveness. For this purpose, it is provided according to the embodiment selected for FIG. 3 that the beveled flan ke between the upper edge 9 and the lower edge 10 is covered on egg ner large width B with a conductor piece 3 c. In addition, parallel to the strip conductors 3 and 3 ', at least one, for example two film strips 26 and 26' with significantly greater width b 'than the width b 1 of the conductor strips 3 and 3' on the stage 7 hinwegge leads. This corresponds to the strip 13 of FIG. 1 strips 26 and 26 'are not connected to the upper Leiterstük ken 3 a and 3 a' of the conductor strips 3 and 3 ', but with the end on the flank of the level conductor portion 3 c, and optionally also with the lower conductor pieces 3 b and 3 b 'of the conductor strips 3 and 3 ' connected via a wide transverse strip 27 . The width b 2 according to Fig. 1 is thus in this embodiment the sum of the widths b 'and b 1 for each of the elements 2 and 2' hen anzuse. The strips 26 and 26 'form with the transverse strip 27 an approximately C-shaped, to the conductor piece located on the flank 3 c connected and the step bottom edge 10 over a large area bridging conductor structure 30th This conductor structure can be connected to a connection conductor at a contact surface 31 .

In the embodiment of Lei terstruktur 30 shown in Fig. 3, it was assumed that the conductor strips 3 and 3 'at the lower level of stage 7 pass into the conductor structure. In order to avoid the formation of parasitic SQUIDs, however, the conductor structure and the conductor strips can also remain unconnected in this area.

As can further be seen from FIG. 3, in principle only the conductor piece 3 c located on the beveled flank 3 c from an HTS film is required to close the SQUID loop 21 . This conductor piece is only a few micrometers extended between the edges 9 and 10 , but has a much larger width B of z. B. 10 to 100 microns. The SQUID loop is partially closed without a grain boundary. Virtually no part of the SQUID loop lies on a part of the substrate that has been deepened by etching, where the quality of an HTS film is not essential, but is noticeably worse than on the unetched part. Only a signal and bias contact required for such a SQUID must be guided over the bottom edge 10 . There, however, the grain boundary is so large due to the large conductor width that it practically always acts like a superconducting short-circuit and therefore does not impair the signals passed over it. A corresponding SQUID can therefore also be referred to as a "Stay Above" SQUID.

Since the SQUID loop 21 according to FIG. 3 is closed in the area of the beveled flank between the edges 9 and 10 , the corresponding conductor piece 3 c can also be extended laterally according to the supervision of FIG. 4 and into a substantially wider film strip 33 pass, which covers stage 7 over a large area and is provided with a contact surface 34 .

Deviating from the embodiment of a DC-SQUID not shown to scale in FIGS . 3 and 4, SQUIDs can also be constructed with only one Josephson element according to the invention. For this purpose, one of the two conductors strips 3 or 3 'in such a width across the step 7 that the grain boundaries formed both on the upper edge 9 and on the lower edge 10 are practically short-circuited.

For the exemplary embodiments shown in the figures it was assumed that the basis of the Josephson elements is a substrate according to the invention, in which in particular a step is incorporated by an etching process. Of course, a flat sub can also be used as a base serve strat, provided with an epitaxial film whose lateral border is the required level educates (see the reference mentioned at the beginning "IEEE Trans. Magn.").

Claims (11)

1. Grain boundary Josephson element with metal oxide high temperature (HTS) material on an epitaxial layer which has a step with a beveled flank between a grain boundary inducing upper edge and a grain boundary inducing lower edge, with strip-shaped conductor pieces made of the HTS material over the step Extend with a predetermined width, characterized in that a middle res, on the flank ( 11 ) between the upper edge of the step ( 9 ) and the lower edge ( 10 ) extending conductor piece ( 3 c) and at least one lower, at the bottom edge of the step ( 10 ) to this middle conductor piece ( 3 c) angren zendes conductor piece ( 13 b, 26 , 26 ', 33 ) are provided, the width (B or b 2 , b') is larger than the predetermined width (b 1 ) an upper, on the upper step edge ( 9 ) to the middle conductor piece ( 3 c) adjacent conductor piece ( 3 a, 3 a '). 2. Josephson element according to claim 1, characterized in that the conductor pieces ( 3 a, 3 a ', 3 c, 13 b) at least two conductor strips ( 3 , 3 ', 13 , 26 , 26 ') running parallel to the step ( 7 ) , 33 ) are to be assigned, one conductor strip ( 3 , 3 ') the predetermined width (b 1 ) of the upper conductor piece ( 3 a, 3 a') and the other conductor strip ( 13 , 26 , 26 ', 33 ) Comparatively larger width (b 2 , b ') of the lower Lei terstückes ( 13 b) and these conductor strips ( 3 , 3 ', 13 , 26 , 26 ', 33 ) connected to each other at least via the middle Lei terstück ( 3 c) are. 3. Josephson element according to claim 1 or 2, characterized in that the lower step edge ( 10 ) is bridged over a width (b 2 , b ') which is at least three times as large as the width (b 1 ) of the upper conductor section ( 3rd a, 3 a,). 4. Josephson element according to one of claims 1 to 3, characterized in that the middle conductor piece ( 3 c) is connected laterally on the flank to a conductor strip ( 33 ) which bridges te at least the lower edge of the step ( 10 ) in a wide range (cf. Fig. 4). 5. Josephson element according to one of claims 1 to 4, characterized in that the angle of inclination (α) of the flank ( 11 ) relative to the plane (E 1 ) of the upper edge of the step ( 9 ) adjoining the upper conductor section ( 3 a, 3 a ') is at least 45 °. 6. A method for producing a Josephson element according to one of claims 1 to 5, characterized in that the structuring of at least one of the at least one of the upper edge of the step ( 9 ) bordering the upper conductor piece ( 3 a, 3 a ') by means of a beam ( 17th ) takes place, which is aligned at an angle with respect to the plane (E 1 ) of the upper conductor section ( 3 a, 3 a '), which is at most as large as the angle of inclination (α) of the flank ( 11 ) with respect to this plane. 7. The method according to claim 6, characterized in that a corresponding lacquer layer ( 16 ) is structured by means of a directed light beam to form a mask for a photolithographic step. 8. The method according to claim 6, characterized in that from an HTS film ( 15 ) in an etching process by means of a directed ion beam ( 17 ) at least one at least one of the upper step edge ( 9 ) adjacent upper conductor piece ( 3 a, 3 a ' ) is structured. 9. The method according to claim 6, characterized in that a structuring of a film ( 15 ) from the HTS material at least to the least least an upper conductor piece ( 3 a, 3 a ') takes place in that before the deposition of the HTS Films ( 15 ) on the base ( 4 ) an orderly crystal structure of the HTS material preventing auxiliary material is applied at the locations of the base ( 4 ), where an orderly growth of this material is to be prevented when the HTS material is deposited . 10. The method according to claim 6, characterized in that a structuring of a film ( 15 ) made of the HTS material at least to the little least an upper conductor piece ( 3 a, 3 a ') takes place in that an ordered crystal structure of the HTS -Materials auxiliary material is deposited at the locations of the HTS film ( 15 ), where the superconducting properties of the HTS film ( 15 ) are to be destroyed by subsequent heat treatment. 11. Use of at least one Josephson element according to one of claims 1 to 5 for building a SQUID ( 20 ) whose SQUID loop ( 21 ) has a lateral slot ( 23 ) on the flank ( 11 ) by means of the conductor piece located there ( 3 c) is closed.