DE4003308C2 - Device for the detection of micromagnetic or microelectric fields - Google Patents

Description

The invention is based on a device for detection of the micromagnetic object emerging from a magnetic field generating object or microelectric field with a modified Electron microscope part, in the vacuum space an electron beam is to be led through the field of the measurement object, and with a subordinate readout part for evaluation and display the intensity distribution of the in the field of the measurement object deflected electron beam. Such a detection device is published in the publication "IEEE Trans. Magn. ", Vol. MAG-20, No. 5, Sept. 1984, pages 866 to 868 described.

With the known device, the magnetic field can indirectly magnetic field generating test object (test persons) detected will. For this purpose, a modified scanning electron microscope is used in the vacuum space a sharply focused electron beam in the immediate vicinity of the magnetic field generating object passed by. In the case of the measurement object, it can in particular be a thin film magnetic head for a data storage system act in a limited volume a magnetic Stray field generated. Corresponding fields are extremely weak. So z. B. on the pole mirrors of the magnetic poles of such magnetic heads Field strengths on the order of only 100 kA / m too measure up. Such magnetic fields are therefore also called micromagnetic Designated fields.

In the known detection device, the electron beam is deflected by the components of the magnetic induction B _x or B _{y of} the stray field of the measurement object in the corresponding y or x direction in an assumed xy coordinate system. The components of the magnetic induction can then be calculated from the size of the deflection of the electrons. In order to make the electrons visible, the deflected electron beam first hits a microchannel plate in the known detection device, which is followed by a phosphor layer. In this phosphor layer, the electron intensity distribution is converted into a light intensity distribution. The light now emerging from the vacuum space of the electron microscope is then fed via transfer optics to a TV camera, with which the light intensity distribution can be observed as a function of the stray field of the measurement object.

However, it has been shown that this known Detek tion device of the light generated in the phosphor layer stain is relatively large and smeared, so that at a point measurement the image generated by the electron beam must be captured by electronic image processing and Only then the center of gravity is calculated can. The time to take a line measurement at which a variety of point measurements must be made, be therefore carries many minutes. Such a long measuring time can, however, especially with thin film magnetic heads with a very low Distance between the measuring plane of the electron beam and the Pole mirror of the magnetic head of z. B. only about 0.5 microns Charging of the test object generating the field to be detected and thus a falsification of the measurement result due to cause electrostatic interactions. In addition, the known detection device of the equipment effort pictorial representation of the intensity distribution of the distracted ten electron beam relatively high.

Furthermore, in the publication "IEEE Trans. Magn.", Vol.  MAG-21, No. 5, Sept. 1985, pages 1593 to 1595 a corresponding tomographic measurement method to a three-dimensional Determination of the stray fields of a magnetic head described. This is one of the detection devices outlined above appropriate institution is used, but at the the object producing the magnetic field is rotated by a total of 180 ° and performed a line measurement at every angle setting becomes. With thin-film magnetic heads are the required short working distance due to the charging problem mentioned corresponding three-dimensional measurements without a significant Acceleration of the measuring process in practice not feasible.

The object of the present invention is therefore the detection device with the characteristics mentioned above to design that with her a quick two or three-dimensional measurement of micromagnetic fields with Using the electron beam of an electron microscope and at the same time the required equipment is limited.

This object is achieved by the features specified in claim 1.

The invention is based on the knowledge that a conversion of the electron beam intensity into a Light  intensity can be omitted if one of the invention Uses photodiode for reading. One on the p- and the n- Layer of the photodiode impinging electron beam generated namely an additional stream there. The so firm adjustable current changes in these layers are then a direct measure of the coordinates of the electron deflection beam and thus for the corresponding components of the magne table induction of the test object. With this configuration the Detection device are particularly the advantages in it see that the measurement time to determine the location coordinates the center of gravity of the electron beam compared to known Detection devices can be reduced considerably.

Advantageous refinements of the detection according to the invention establishment emerge from the subclaims.

To further explain the invention, reference is made below to the drawing, in FIG. 1 of which a detection device according to the invention is outlined. Fig. 2 shows schematically an oblique view of a photodiode of the readout part of this detection device. In the figures, corresponding parts are provided with the same reference numerals.

In Fig. 1 the basic structure of a detection device according to the invention is schematically illustrated. Embodiments known per se are used as a basis here (cf., for example, the text passage mentioned from "IEEE Trans. Magn.", Vol. MAG-20). The generally designated 2 detection device includes, inter alia, a part 3 designed as a modified scanning electron microscope. This constructed in known manner ter electron microscope part 3 includes intra-half of the vacuum space 4 of its vacuum housing 4 a a Elek tronenstrahlquelle 5, with which an electron beam is generated. 6 After this beam has passed through the usual electrostatic or electromagnetic lenses 7 a and 7 b, it enters a magnetic field of low strength to be detected, for example between 10 and 500 A / m. This magnetic field or its associated induction B is caused by an object 10 producing a magnetic field which is introduced into the vacuum space 4 . This measurement object 10 can in particular be a magnetic head created in thin-film technology, as is customary for data storage systems. Due to the Lorentz forces acting on the electron beam 6 in the magnetic field, the electron beam 6 is deflected accordingly in the x and / or y direction of an assumed xy coordinate system. The deflection is a measure of the magnetic induction B. The deflection angle α is shown exaggerated in the figure and is generally only a few degrees.

The deflected and denoted by 6 'electron beam should then according to the invention directly on a downstream in the vacuum chamber 4 special photodiode 20 of a readout part of the device. With this readout part, the intensity distribution of the deflected electron beam can be evaluated and displayed. In other words, in the detection device according to the invention, the parts which are otherwise present in known detection devices for converting the electron beam intensity into a light intensity and then the parts required for light transmission can advantageously be omitted. The particular advantage of the inventive design of the detection device can be seen in the associated extremely high sensitivity, which can be up to a factor of 600 to 800 higher compared to the known embodiments. Therefore, very small beam currents of, for example, about 50 pA or less can advantageously be used, which prevents the measurement object from being charged, particularly in the case of a tomographic measurement method.

The photodiode 20 has a pronounced two-dimensional shape and is sensitive to the x and y direction of the deflected electron beam 6 'striking it. Their design is illustrated in more detail in Fig. 2. According to the schematic oblique view shown in this figure, the photodiode 20 contains, in a manner known per se, two mutually parallel planar layers 21 and 22 , of which e.g. B. the incident electron beam 6 'facing layer 21 has a p-type doping. Then the layer 22 must have an n-doping. A protective layer possibly present on the flat side of the photodiode placed on the electron beam was advantageously removed beforehand or at least thinned so far that the electrons with an energy of, for example, 15 keV can penetrate this protective layer without significant losses. The alignment of the photodiode is such that the extension of the undeflected electron beam 6 is at least approximately perpendicular to the upper flat side of the photodiode or a detection area 23 of the p-layer 21 . Since the deflection angle α between the non-deflected electron beam 6 and the deflected beam 6 'is very small, an almost vertical right entry of the beam 6 ' into the detection region 23 is assumed in the illustration in FIG. 2. Between the two layers 21 and 22 of the photo diode 20 there is an undoped, so-called "intrinsic" intermediate layer 24 . Consequently, the embodiment shown in the figure is based on a photodiode of the so-called "pin" type. However, other types of photodiodes with p and n layers are also suitable for the detection device according to the invention. On the edges of the p-layer 21, which are spaced apart in the x-direction of an assumed xy coordinate system, two strip electrodes 25 a and 25 b parallel to one another are applied, for example vapor-deposited. Between these stripe electrodes is the incident electron beam 6 'exposed detection area 23 of the layer 21 . Correspondingly, the n-layer 22 also has two strip electrodes 26 a and 26 b with the detection region 27 for the electron beam 6 'in between. These strip electrodes 26 a and 26 b, however, are arranged rotated by 90 ° with respect to the strip electrodes 25 a and 25 b and are therefore located on the edges of the layer 22 which are spaced apart in the y direction. Electronics connected to the electrodes and not shown in the figure is known per se.

With such a two-dimensional, position-sensitive photodiode, the center of gravity of an electron spot can now be measured directly. For this purpose, e.g. B. the electrodes 25 a and 26 a are each set to constant potential and currents occurring at the electrodes 25 b and 26 b are measured. Now hits an electron beam 6 'at a location with the coordinates x and y of the photodiode 20 , it generates an additional current which flows evenly to all sides. Therefore, the current change detectable at the electrode 25 b is proportional to the length x and the current change at the electrode 26 b is proportional to the length y. The measuring time for changing the current x, y of the electron center of gravity can thus be reduced by at least 90% compared to the known detection devices with a TV camera.

According to the embodiment on which the figures are based, it was assumed that with the detection device 2 according to the invention a two-dimensional determination of the micro-magnetic field of a magnetic-field-producing measurement object 10 is detected. A detection device according to the invention can equally well be designed in such a way that it enables a three-dimensional measurement. The constructive means required for this are known per se (cf., for example, the cited reference from "IEEE Trans. Magn.", Vol. MAG-21). With them, a rotation of the magnetic field-generating measurement object is to be carried out about an axis lying perpendicular to the electron beam 3 generated in the electron microscope 3 . With a view to achieving the highest possible measurement accuracy with a measurement error of z. B. only a few percent and a measurement time as short as possible, about 45 different angles are advantageously set in the tomographic measurement and about 60 point measurements are carried out in each case. If a measurement error of around 10% can be tolerated, only 40 angle settings with 50 point measurements are required. For orientation measurements with an error of up to 25%, 30 angular positions and 40 point measurements can be sufficient.

One for operating the detection device according to the invention required electronics is known per se (cf. e.g. the ge called reference "IEEE Trans. Magn.", Vol. MAG-20). On a pictorial representation was therefore omitted.

Furthermore, it goes without saying that the De tection device and the method on which it is based Detection of micromagnetic fields just as well on a De tection of microelectric fields are applicable.

Claims (4)

1. Device for the detection of the emerging at a field-generating object to be measured magnetic or micro-electric field with a modified electron microscope part, in the vacuum space of which an electron beam is to be guided through the field of the object to be measured, and with a downstream read-out part for evaluating and displaying the intensity distribution of the in the field of Object of the deflected electron beam, characterized in that a two-dimensional, position-sensitive photodiode ( 20 ) is provided for the readout part, which is directly exposed to the deflected electron beam ( 6 ') in the vacuum space ( 4 ) of the electron microscope part ( 3 ) and two mutually parallel layers ( 21 or 22 ), one of which is p-doped and the other of which is n-doped and whose deflected electron beam ( 6 ') is exposed to detection areas ( 23 , 27 ) each between two parallel strip electrodes ( 25 a, 25 b or 26 a, 26 b ) extend, and that the electrodes ( 25 a, 25 b) of the p-layer ( 21 ) are aligned perpendicular to the electrodes ( 26 a, 26 b) of the n-layer ( 22 ). 2. Detection device according to claim 1, characterized in that the photodiode ( 20 ) between its p-layer ( 21 ) and its n-layer ( 22 ) has an undoped intermediate layer ( 24 ). 3. Detection device according to claim 1 or 2, characterized in that on one electrode of the electrode pairs ( 25 a, 25 b or 26 a, 26 b) of the p-layer ( 21 ) and the n-layer ( 22 ) a constant electrical potential is set and that means are provided for measuring the currents occurring at the other electrodes. 4. Detection device according to one of claims 1 to 3, characterized in that means for rotating the field-generating object ( 10 ) are provided about an axis perpendicular to the electron beam ( 6 ).