DE2211358C3 - Magnetic domain travel direction - Google Patents

Description

The invention relates to a magnetic domain locomotive having local areas of spatial Stability for magnetic domains, consisting of a substrate and on the substrate in a predetermined Pattern of deposited thin layers of magnetic domain material.

Magnetic domains and their propagation in a domain material are from US patents 34 60116, 34 70 546 and 35 08 225 known. In these Patents is the movement of a magnetic domain in a shift register using a tight metal pattern controlled. The repulsive forces are attempted by the method described to make as small as possible between the individual magnetic domains by removing the individual magnetic domains be separated from each other by a distance that is at least three or more times one Magnet domain diameter is. So it is tried to act between the magnetic domains Eliminate forces or at least make them as small as possible.

A magnetic domain locator may consist of one or more channels or strips consist of magnetic domain material «; which are arranged on a support substrate. There can be several Magnetic domain channels are connected to each other or to a main channel. The locomotion of the Magnetic domain along a channel or strip wire of repulsive forces between those in a cana affects existing magnetic domains, e.g. B. who a magnetic domain is formed or moved. Tue < Movement of a magnetic domain from one channel ii to another, adjacent channel to form a Logic function can be achieved by the presence or absence of magnetic domains in adjacent Channels can be controlled.

From the DT-OS 19 10 584 a magnetic domains locomotion device of the type mentioned at the beginning

Known In this known device, wedge-shaped stripe patterns are used to move the domains made of magnetic material. The wedge shape can be in width (Fig. 3, 4 of the DT-OS 19 IC 584) or in the Thickness (Fig. 6) run. This magnetic domain locomotive is, however, quite limited in its application possibilities, since the domains are only in move in one direction.

The object of the invention is to create a MagnetiAJniänenfortfindungs- device in which the Domains can move in at least two directions, preferably in four directions.

According to the invention, the object is achieved by that the deposited thin layers form at least two areas of constant thickness, one being Area that has approximately the same extent in length and width, has a greater thickness than another Area that completely surrounds and isolates the first area

By completely isolating the area of greater thickness and by its approximately equal Expansion in length and width manages to move the domain in more than one direction.

This locomotion in more than one direction is still supported if according to an advantageous one Further areas of the invention are provided, which also have a greater thickness than the first area and from this have such a distance that the domains are shifted there can be.

In further subclaims 3 to 11 are still more precise information about the thickness, arrangement and shape of the areas is given.

The claims 12 and 13 show how by particular Formation of the areas preferably arise directions of movement for the magnetic bubbles without the Direction of movement is inevitable, as in the prior art.

The magnetic domain moving device according to the invention consists of a single crystal substrate, on which a thin layer of likewise monocrystalline magnetic domain material is deposited. The thin Layer has several isolated thicker areas surrounded by thinner areas. When Magnetic domains are formed in the thin layer, they preferentially move into the thicker one Areas. The surrounding, relatively thinner areas of the layer serve as an energy barrier for the Movement of the magnetic domains and thus keep the magnetic domain in the thicker area of the layer. The magnetic domains can be moved from these thicker areas using conventional methods of locomotion can be moved away in a variety of directions.

The thicker areas surrounded by the thinner areas can have a truncated cone shape exhibit. Bubble domains prefer to move in a "slight" direction of motion, namely from the wider end of the truncated cone to the narrower end of another adjacent truncated cone. the reverse direction namely from the narrower end of a truncated cone to the broad end of an adjacent one Truncated cone, represents a "more difficult" direction of movement. The movement of magnetic domains in the "easier" direction requires less force than when moving in the direction of the "more difficult" Direction of movement is the case. This results in a magnetic domain locomotion device which preferably has a direction of movement

Further advantages and possible applications of the invention emerge from the illustration of a Execution example as well as from the following description. It shows

1 shows a plan view of the magnetic domain movement device according to the invention,

FIG. La shows another embodiment of the device according to FIG. 1,

2 shows a cross section through the device according to Fig. 1.

2a shows a cross section through the device according to FIG. la, and

3 shows a representation of the energy curve along a trajectory for a magnetic domain.

The magnetic domain transport device according to the invention consists of a substrate 10 Single crystal material on which a thin layer 12 of likewise single crystal magnetic domain material is deposited is. The thin layer 12 has isolated areas 14 of greater thickness, that of areas smaller thickness are surrounded. The thicker areas of the thin layer represent the lower energy levels for the bubble domains when a magnetic field is perpendicular to the surface of the magnetic domain locator is created. The magnetic domains are preferably arranged in the thicker areas of the thin layer, the lower ones Have energy level. The thinner areas of the layer surrounding the thicker areas have a higher energy level and in this way serve as a barrier against movement of the magnetic domains, thereby keeping the magnetic domain within the thicker area.

External magnetic forces are conventionally used to separate a magnetic domain from a move thicker area to another thicker area of the layer. A magnetic domain can be from one thicker area in each direction to another thicker area. For example can move a magnetic domain from a thicker area up, down, left or right to it moved to another thicker area. The magnetic domain can also be between two thicker ones Areas or to any other number of thicker areas be moved.

If the thicker areas are designed in the shape of a truncated cone, the result is, as already stated, a preferably direction of movement for the magnetic domain. This preferred direction runs from the broad end of one thick area to the narrow end of another thick area. A movement in reverse Direction requires a much higher external force.

The in the F i g. 1, 1 a, 2 and 2a thin layer shown 12 made of magnetic domain material is applied to the monocrystalline by means of a chemical vapor deposition process Substrate 10 deposited. After deposition, the thin layer 12 is etched by several in proportion to obtain thick areas 14 which are surrounded by relatively thin areas 16. The thickness of the Areas 16 is therefore less than the thickness of the areas 14. The shape of the area 14 is preferred rectangular or circular (see F ii g. 1 and 2), but can also be designed as a truncated cone, with the thicker area has a wide and a narrow end (see. Fig. La and 2a). The thicker areas 14

are completely isolated from the thinner areas 16 and thus appear as islands on the layer 12th

The substrate 10 is preferably a monocrystalline garnet which has a UsQsOiz composition. The J component can consist of cerium, praseodymium, neodymium, promethium, samarium, europium, gadolinium, terbium, dysprosium, holmium, erbium, thulium, ytterbium, litetium, lanthanum, yttrium, calcium or bismuth. The Q component can consist of indium, gallium, scandium, titanium, vanadium, chromium, manganese, rhodium, cicronium, hafnium, niobium, tantalum, aluminum, phosphorus, arsenic or antimony. Examples of suitable substrate materials are as follows: Yoas, Gd ₂ J ₅ , Ga ₅ Oi ₂ , Dy _0-65 , Gd ₂ J ₅ , Ga ₅ Oi ₂ and SnIsGa ₅ Oi ₂ .

The thin layer 12 preferably consists of a single crystal garnet of a JaQsOir composition, the J component of cerium, praseodymium, neodymium, promethium, samarium, europium, gadolinium, Terbium, dysprosium, holmium, erbium, thulium, ytterbium, litetium, lanthanum, yttrium, the Q-component from iron, iron and aluminum, iron and gallium, iron and indium, iron and scandium, iron and titanium, iron and vanadium, iron and chromium, iron and manganese.

Preferably materials for the thin layer are iron grenades, such as e.g. B. YsGauFewOtf and Tb3pesOi ₂ .

The magnetic domain moving device has a thin layer with a specific one Magnetostriction constants and a given difference between the lattice constants of thinner Layer and substrate

Garnets are preferred materials for the thin layer, while others are also used for the substrate Materials can be used, especially if the thin layer is made of an orthoferrite material is formed.

The regions 14 are preferably used by means of photolithographic etching processes made of e.g. hot phosphoric acid The hot phosphoric acid etches the areas free from a mask - The layer IZ whereby the relatively thin areas 16 arise. The masked areas of the Layer 12 that are not etched form the thick ones Areas 14. Chemical etching can use other methods, e.g. B. Injection Etching or laser processing.

The size of the areas 14 is not critical; however, the size of the bay should be larger than the size of the magnetic domains which are formed in the respective layer; In this passport, the diameter of the area 14 should be of the order of magnitude of u, tf0Doii or large arcs. if it is appropriate for the blandest applications, the area 14 is as large as possible. “If a Magnetdo gut wifgPnoHinttai wctduu can” it is also possible. make the area 14 so large that seas Energy level in the area 14 is lower than in the adjacent area 16. The surrounding area 16 with a higher energy level acts as a barrier against movement of the magnetic domain:

S out of the thick area. The size of the restraints force provided by the thinner area 16 is inversely proportional to its thickness. The dickei the surrounding area is 16, the smaller di <becomes Restraint If, for example, the Bereicr 16 has 90% of the thickness of the area 14, the magnetic domain is held less firmly in the area 14, ah if the area 16 has a thickness of only 50% de; Area 14 accordingly, the size of the restraint force between different areas U.

ι S by controlling the thickness of the thinner areas K be brought to the desired level. One of the key benefits of magnetic domain locomotion Transmission facilities with spatial stability is the ability to zi a magnetic domain in two directions move, e.g. B. in an X and a y direction. For example, according to FIG. 1, a magnetic domain can be moved in the A "direction along the lines shown there, for example from column A to column E or from column I to column A. Correspondingly, a magnetic domain can also be moved maneuver in any of the columns in the Y-direction, e.g. B. in column A from row 1 to row 5 or before row 5 to row 1. The magnetic domains can be moved from one row to another and from one column to another in any combination. This Flexibility is a very valuable aid and eliminates the disadvantages of the state mentioned at the beginning; of technology that only moves in one direction allows either only in the X-direction or only in the K-direction.

The magnetic domains in the areas 14 can be moved horizontally, vertically and / or diagonally. The geometrical arrangement of the regions 14 shown in FIG. 1 can also be modified. For example, it would be possible to create a first area U to be provided by several other areas U is circularly surrounded, however, the in F i g. 1 die shape shown is a particularly favorable one

Arrangement. Another possibility to arrange the areas 14

nen, is to make a hexagonal shaped first Area 14 to arrange six further areas 14, which are equally spaced apart, also hexagonal. In this case, a magnetic domain can be provided first area 14 in six different directions

so be moved.

The area 14 can be shaped aochoctogoaal nnc be surrounded by eight giekhmäSig in Aistand arranged areas 14, which also wkdea are octagonal. Then a magnetic domain of

SS first area 14 to be shifted in eight rs direction.

Due to the described Ffegdbäität dk can invent according to German

Like;

aefdn

Aänen IS become aafache way

bathed by placing a suitable gld over the the structures shown. The magnetic domains 17, 18 can grain in an area or else iamehraen areas 14 can also be bathed. In the the thorny bay 12 bathed magnetic domain 17,18 is in the thicker area 14 because the gg

tong can be used in many ways. Additional application dnng as cheregister ISr Verfaräj ^ ngseinricmtiH gen is also an application in security systems, be phone dialing anlniHigeno.dgLniSfpEäL

wtHiEO Kegemuuujumuuge iserasne 14 verwenoci can also use these in the form of columns end ZeSeI aag, as shown in Fig. La is Dk Bgtai l ^ gen tJeracae 14 oesazen eai scamafa

gen areas 14 are

p svmmetnsci

arranged, d. that is, one wide end of a thick region 14 adjacent to the narrow end of an adjacent Area 14 is located. For example, the wide end 22 of the frustoconical area 20 is closest to narrow end 26 of the adjacent frustoconical area 24.

The frustoconical area 14 can be arranged with its narrow end so that the narrow part points to "west", see Fig. la; but he can also follow Point "north", "east", "south" or in a direction in between. For example, in in one line the narrow ends 26 point in the "east" direction, in a second line in the "west" direction.

The magnetic domains 17 arrange themselves automatically in the frustoconical regions 14 in the position 18 with the lowest energy, as in FIG. 1 and shown in Fig.3. Magnetic domains can be moved from and to adjacent areas 14 in this way. For example, a magnetic domain may be moved along the "easy" direction of movement through the broad end 22 of the frustoconical region 20 and through the narrow end 26 of the frustoconical region 24. This "slight" direction of movement only requires a relatively small force to move the magnetic domain. It is particularly favorable if the preferred direction of movement of the magnetic domain coincides with the "easy" direction of movement. By choosing the external force suitable for the magnetic domain movement, the magnetic domains only move along the "easy" direction, since movement in the opposite direction would require too much force. The force required for movement is defined by the change in energy per change in length (F = άΕΙάΧ). The force required for magnetic domain movement is shown in FIG. 3 as slope (άΕΙάΧ)

ίο the curve (energy over distance) is shown. the force required to move, d. H. the slope is from 28 to 30 (Fig. 3) along the "easy" direction from area 20 to area 24 smaller than the slope from 32 to 30 along the "difficult" one. Direction from Area 24 to Area 20.

By arranging the frustoconical areas accordingly, it can be achieved that the "light" Direction of movement is in the desired direction. By using such frustoconical

ao areas and through the movement of the magnetic domains along "easy" directions of movement results in a unidirectional path for the magnetic domain. However, the magnetic domains can also be longitudinal shifted in the "difficult" direction of movement

“5, but this requires greater powers than they do a shift along the "easy" direction are required.

For this purpose 2 sheets of drawings

Claims (13)

Patent claims: 1. Magnetic domain locator with local areas of spatial stability for magnetic domains, consisting of a substrate i »nd of thin layers of magnetic domain material deposited on the substrate in a predetermined pattern, characterized in that the deposited thin layers (14, 16) at least two areas each having a constant thickness, wherein · a region (14) which is approximately same expansion in length and width has a greater thickness than another area (16), which completely surrounds and isolates the first area (14). 2. Magnetic domain locomotion device according to claim I _1, characterized in that a plurality of areas (14) of a third thickness are provided which are greater than the thickness of the surrounding area (16), and that the plurality of areas (14) from the first area ( 14) are spaced such that a domain can be shifted from the first region (14) to the plurality of regions (14). 3. Device according to claim 2, characterized in that the thickness of the first region (14) in is essentially the same as that of the plurality of areas (14). 4. Device according to claim 2 or 3, characterized in that the plurality of areas (14) in is arranged in a pattern around the first region (14). 5. Device according to claims 2, 3 or 4, characterized in that at least two of the A plurality of areas (14) are arranged on opposite sides of the first area (14). 6. Device according to one of claims 2 to 5, characterized in that at least two of the A plurality of the regions (14) are arranged so that they form an angle of approximately 90 ° with the first Form area (14). 7. Device according to one of claims 2 to 6, characterized in that the shape of the first Area (14) is round. 8. Device according to one of the preceding claims 1 to 7, characterized in that in addition to the first area (14) and the surrounding area (16), a second area (14) and a third Area (14) are provided which each have a greater thickness than their surrounding area (16) that the second area (14) is arranged in X-directions with respect to the first area (14), one domain being movable from the first to the second area (14), and the third Area (14) is arranged in the V-direction with respect to the first area (14), with a domain from first to the third area (14) can be moved. 9. Device according to claim 8, characterized by a fourth region (14) with a thickness which is larger than that of the associated surrounding area (16), the fourth area (14) being the first Area has such a distance that a domain from the first to the fourth area (14) can be moved, and through a fifth area (14) with a thickness that is greater than that of the associated surrounding area (16), the fifth area (14) being one of the first area such a distance that a domain from first to the fifth area (14) can be moved. 10. Device according to one of the preceding claims 1 to 9, characterized in that the Areas are etched. 11. Device according to one of the preceding Claims, characterized in that it can be used as a four-part shift register 12. Device according to claim 1, characterized in that a first region (14) and a second area (14) each have a frustoconical shape with a narrow end (26) and a have wide end (22), the second region (14) to the first region (14) in such a way tst that a domain from the first region (14) through its wide end (22) to the second part can be moved through the narrow end (26). 13. Device according to claim 12, characterized in that a plurality of frustoconical second areas (14) are provided which are in linear spacing relation to the first area (14), the narrow ends (26) being uniform and symmetrical from one another Own distance.