DE4443025C2 - Method and device for scanning magnetic microscopy - Google Patents

Description

The invention relates to a method for measuring a Surface of a test object with a permanent magnetic field des as well as a facility for performing the method.

To measure the field strength z. B. Vibration magnetometer used where one or more measuring coils above the test ling swing. For example, DE-AS 12 94 550 gives a vibration mag netometer with two lying in one or in parallel planes the vibrating measuring coils, the abge the measuring coils received signal contains a component that is proportional to the Tangential component of the magnetic field strength at the point around which the measuring coils swing.

Furthermore, DE 43 43 225 C2 describes a method for zer known trouble-free material testing, in which a test object with a periodically changing magnetic field and sound waves is applied, the magnetization processes with ei Nem inductive sensor can be detected, the paral in one plane lel is arranged to the test object.

Y. Honda et al also disclose a magnetic force microscope, at which vibrates a magnetic tip Cobalt is attached to a lever arm and this by means of egg nes xyz scanner is moved linearly over a test object, with the magnetic attraction of the test object Frequency of the vibration is changed and so to measure the magnetic field strength can be used.  

However, with all of the previously known methods, prinzi only measure the tangential component of the magnetic field, that prevails on the surface of the test object, whether permanent or periodically impressed on it for material inspection. The magnetic circuit is largely through the air, which leads to wastage and errors.

The object of the invention is a method and a device tion to carry out the method for measuring the orthogo nalen component of the magnetic field strength, which at the upper surface of a test object occurs.

This object is achieved by a method with the in claim 1 Features specified or by a device with the in Claim 7 specified features solved. Special execution Types of the invention are the subject of the dependent claims.

In addition to application in general materials testing and Quality assurance is this procedure for use in for predestined research and development area, e.g. B. at Ma save gnetbubble.  

Accordingly, it is essential in the method according to the invention that the Sample for their relative movement in the x-y direction or rotating or rotating-shifted additionally in high-frequency vibrations ver is set, which can be done in any direction, preferred however, is orthogonal to the motion vector, i.e. H. in z or x or y direction. This additional movement, the grid movement ü is superimposed leads to a virtual relative speed of over three meters / second at a frequency of 10 kilohertz and an amplitude of 100 micrometers.

In a continuation of the inventive idea, it is proposed that to close the magnetic circuit through the sample, being next to the be Known measuring methods such measurements using impressed magneti alternating frequency and amplitude can be taken. In this way, z. B. the Koerzi Measure the field strength of a Weiss district or its influence on alternating fields, their strength below the remanence point lies. Information can also be shouted to the test be.

A test tip is advantageously made of a thin platinum wire made on the two soft magnetic layers z. B. from Iron through a non-magnetic or diamagnetic layer, such as bismuth, are separated, these layers being applied electrolytically become.

Furthermore, a test probe can be pulled out by pulling out a wire make, which is made of non-magnetic or diamagnetic material embedded soft magnetic probe and shielding wire or wires consists.

In addition to the pie, it is essential for the device according to the invention zomechanical vibration exciter the probe, which consists of a test  and supply peak exists. These tips are replaced individually selectable and magnetically ver with each other over the supply area bound. Since both a read and a write operation are possible , it may be advantageous to use the coil and / or individual measuring track len to short-circuit or bridge magnetically. By the mag net shielding of the test probe and measurement of the probe and / or the shielding circuit has a resolution of approximately the size of Reach probe wire diameter. By dividing the shield circle and separate measurements can be additional In win formations. A change in distance from test and / or probe tip and their evaluation possible.

The arrangement of several test probes in one is also advantageous or several, preferably staggered rows to one Reading line, with a correspondingly shaped supply bar. The writing is done by impressing a magnetic field into the desired probe circle.

In addition to a relatively high scanning speed, this stands out Process through a simple and robust structure, with which reproducible measurement results can also be achieved.

The method according to the invention and the invention are described below device according to the invention with reference to the drawing tert.

It shows:

Fig. 1 is a schematic representation of the probe,

Fig. 2: a section through the test probe along the line II-II in Fig. 1, and

Fig. 3: a schematic representation of the magnetic circuits.

In Fig. 1 a probe 1 is shown for the inventive device which is formed from two magnetic conductors 2. The sample 3 is moved between the test tip 4 and the supply tip 5 , in the xy direction or in a circular or circular motion. Test tip 4 and supply tip 5 can be made tapered to the same or different extent.

Fig. 2 shows a possible embodiment of a test probe in cross section. To the probe wire 7 shield wires 6 are angeord net, wherein the group consisting of magnetically conductive material wires 7 are embedded in diamagnetic bismuth 8. 6

Fig. 3 shows the course of the individual magnetic circuits that emanate from the coil 19 . The calibration circuit 11 is used to calibrate the device, which can also be used to increase the measuring accuracy during operation, the values of the measuring coil 9 being used as a reference variable. The shielding 15 and probe circuit 16 are connected to the working circuit 12 by means of screws 18 for the supply circuit 13 or by means of contact springs 17 . The sample table 14 with corresponding drive devices is located between the supply tip 5 connected to the supply circuit 13 and the test tip 4 , in which the shielding 15 and probe circuit 16 runs. The resolution can be changed by changing the tips 4 , 5 , by selecting the tip diameter and by spacing the tips 4 , 5 from one another. The measuring coils 9 in the supply 13 and shielding circuit 15 deliver z. B. by difference forming the measured value, possibly including the measured value of the measuring coil 9 of the calibration circuit 11 as a reference variable.

Reference list

1.

probe

2nd

magnetic conductor

3rd

sample

4th

Test probe

5.

Supply peak

6.

Shielding wire

7.

Probe wire

8th.

bismuth

9.

Measuring coil

10th

-

11.

Calibration circuit

12th

Working group

13.

Supply circuit

14.

Rehearsal table

15.

Shielding circle

16.

Probe circle

17th

Contact springs

18th

Screws

19th

Kitchen sink

Claims (10)

1. A method for measuring a permanent magnetic field prevailing on the surface of a test specimen by means of a magnetically conductive test probe which is moved linearly over the surface of the test specimen, where at each measuring point on the surface in addition to a measured value proportional to the magnetic field to be measured, a distance value from Test tip is assigned to the surface or a constant distance is maintained by shifting the test tip, value tuples formed from the measured value and the distance value are used for image generation for scanning microscopy methods, characterized in that via the test tip ( 4 ), which has a magnetic rule Conductor ( 13 ) with a magnetically conductive supply tip ( 5 ) is connected, a magnetic circuit is formed from the surface to the opposite side of the test specimen ( 3 ). 2. The method according to claim 1, characterized in that the test specimen ( 3 ) is acted upon orthogonally to the linear movement of the test probe ( 4 ) with a mechanical vibration of variable amplitude and frequency. 3. The method according to claim 1, characterized in that the test specimen ( 3 ) on the test probe ( 4 ), magnetic conductor ( 13 ) and Ver supply tip ( 5 ) magnetic circuit with a magnetic field variable amplitude and frequency is applied. 4. The method according to claim 2 or 3, characterized in that by the magnetic loading of the test specimen ( 3 ) analog or digital information is stored in this. 5. The method according to claim 1, characterized in that the magnetic circuit in the probe ( 4 ) from a shield ( 15 ) and a son denkreis ( 16 ) is formed. 6. The method according to claim 3, characterized in that the magnetic field with which the test specimen ( 3 ) is applied is measured in a parallel calibration circuit ( 11 ). 7. Device for performing the method according to claim 1, characterized in that

• 1. that the test probe ( 4 ) forms at least one magnetic circuit,
• 2. that the magnetic circuit or circuits are continued via one or more magnetic conductors ( 13 ) and a supply tip ( 5 ),
• 3. that a sensor ( 9 ) for measuring the magnetic flux or the magnetic field strength is arranged on or in at least one magnetic circuit, and
• 4. that at least the test probe ( 4 ) is adjustable in the z-axis or at a distance from the surface of the test specimen ( 3 ).

8. Device for performing the method according to claim 7, characterized in that the height of the test probe ( 4 ) an xy table and a piezomechanical vibrator are arranged. 9. Device for performing the method according to claim 7, characterized in that the test ( 4 ) and / or Ver supply tips ( 5 ) are detachably attached to the magnetic circuit. 10. A device for carrying out the method according to claim 7, characterized in that a reading and / or writing line is built up by the arrangement of test probes ( 4 ) in one or more rows set against each other.