RU2737030C1 - Hysteresis loop meter for study of thin magnetic films - Google Patents

Abstract

FIELD: measuring equipment.SUBSTANCE: invention relates to measurement equipment and is intended for detection of hysteresis loops of thin ferromagnetic samples. Device comprises a reverse magnetization field generating system, an oscillograph for observing a hysteresis loop and recording its parameters, novel is that two Hall sensors are used as a sensitive element, located under the analyzed sample of the thin magnetic film so that their maximum sensitivity axes are oriented perpendicular to the direction of the reverse magnetization field and perpendicular to the plane of the thin magnetic film, wherein signal of one of Hall sensors is inverted and summed with signal of second Hall sensor, and third, additional Hall sensor is used for measurement of reverse magnetization field value.EFFECT: simplified hysteresis loop meter design for thin magnetic films.1 cl, 2 dwg

Description

The invention relates to measuring technology and is intended for recording hysteresis loops of thin ferromagnetic samples.

The known method of oscillography of hysteresis loops of thin magnetic films (loophole) [Suhu, R. Magnetic thin films. - M .: Mir, 1967, p. 205]. A petlescope is a device with which it is possible to observe the dependence of the magnetic moment of the sample on the magnetic field applied to it on the oscilloscope screen. The device consists of an audio frequency signal generator connected through a power amplifier and a measuring resistance to a magnetizing pair of Helmholtz coils. The signal taken from the measuring resistance is fed to the horizontal scan input of the oscilloscope. Inside the Helmholtz coils, the measuring and compensating coils are symmetrically placed, and the test sample is placed directly near the measuring coil. Voltage is induced in the measuring coil even in the absence of a film; therefore, to compensate for it, the measuring coil is switched on opposite the compensation coil, which is located far from the sample under study. To facilitate the compensation of the interference voltage, it is possible to adjust the position and orientation of the compensating and measuring coils. An additional pair of Helmholtz rings are placed horizontally and are designed to compensate for the Earth's magnetic field. The signal from the counter-connected compensating coil and the measuring coil is fed to the integrator, the output of which is connected to the input of the vertical sweep of the oscilloscope. The test sample is placed near the measuring coil. The hysteresis loop is observed on the oscilloscope screen. The horizontal scale of the oscilloscope is calibrated in field units, and the vertical scale is calibrated according to a "reference" sample with a known value of the magnetic moment. The magnetic characteristics of the investigated thin-film sample, such as saturation magnetization, remanent magnetization, coercive force and magnetic anisotropy field, are determined from the parameters of the hysteresis loop.

The closest analogue in terms of a set of essential features is a device for measuring the magnetic properties of thin ferromagnetic samples [Ed. certificate of the USSR, No. 386357, IPC G01R 33/14, publ. 06/14/1973, bul. No. 26 (prototype)]. The device contains a source of an alternating magnetic field, a measuring winding, next to which the test sample is located, and connected through an amplifier and an integrator to the vertical deflection channel of the oscilloscope. The horizontal deflection channel of the oscilloscope is connected to an alternating magnetic field source. During the operation of the device, the alternating magnetic field of the source remagnetizes the sample under study, as a result of which an emf is induced in the measuring winding, which is a magnetization reversal signal, which is fed in series to the amplifier, and then to the integrator. An integrated signal proportional to the magnetic flux of the sample under study is fed to the vertical deflection channel of the oscilloscope. As a result, a magnetization reversal process is observed on the oscilloscope screen - a hysteresis loop, according to the parameters of which the magnetic characteristics of a thin-film sample are determined.

A common disadvantage of the known design of the looplescope and the prototype device is their complexity, which consists in the need to manufacture multi-turn small coils of the sensitive element; in the complexity of the implementation of the integrating device; in the need to create a special source of the magnetizing field.

The technical result of the claimed solution is to simplify the design of the looplescope for thin magnetic films.

The claimed technical result is achieved by the fact that in a loop for the study of thin magnetic films containing a system for the formation of a magnetizing field, an oscilloscope for observing the hysteresis loop and recording its parameters, the novelty is that two Hall sensors are used as a sensitive element, located under the test sample of a thin magnetic film in such a way that their axes of maximum sensitivity are oriented perpendicular to the direction of the magnetizing field and perpendicular to the plane of the thin magnetic film, and the signal of one of the Hall sensors is inverted and summed with the signal of the second Hall sensor, and the third, additional Hall sensor, is used to measure the magnitude of the magnetizing field ...

Comparative analysis with the prototype shows that the claimed device is distinguished by the use of Hall sensors as sensing elements instead of multi-turn coils. A significant difference between the claimed design in this case is the absence of a voltage integrator. Another significant difference is the measurement of the magnitude of the magnetizing field with an additional, built-in third Hall sensor, which allows using any external sources of an alternating magnetic field in the looplescope.

Thus, the above-mentioned features distinguishing from the prototype make it possible to conclude that the proposed technical solution meets the “novelty” criterion.

The features that distinguish the claimed technical solution from the prototype are not identified in other technical solutions and, therefore, ensure compliance with the "inventive step" criterion for the claimed solution.

This invention is illustrated by drawings. FIG. 1 shows the design of a looplescope for studying thin magnetic films. FIG. 2 shows the printed circuit assembly of the device with sensitive elements and a sample of a thin magnetic film.

The loop for the study of thin magnetic films contains (Fig. 1) Helmholtz rings (1) connected to the output of the generator (2) low frequency current. Inside the Helmholtz rings (1) there is a printed circuit board (3) with radio components and sensing elements installed on it: the first Hall sensor (4) and the second Hall sensor (5), placed under the test sample of a thin magnetic film (6). An additional Hall sensor (7) is also installed on the printed circuit board (3), which is used to measure the magnitude of the magnetizing field generated by the Helmholtz rings (1). The output of this Hall sensor (7) is connected (Fig. 2) to the input of an operational amplifier (8), on the basis of which a low-pass filter with a unity gain in the passband is implemented. The output of the operational amplifier (8) is connected to the output connector (9), which is connected to the horizontal scan channel of an external storage oscilloscope or recorder. The output of the first Hall sensor (4) is connected to the operational amplifier (10), which implements the function of a signal follower, the output of which, in turn, is connected to the input of the operational amplifier (11), which acts as a voltage inverter. The output of the operational amplifier (11) is connected to the first input of the operational amplifier (12), on the basis of which a signal adder with a low-pass filter is implemented. The output of the second Hall sensor (5) is connected to the input of the operational amplifier (13), which acts as a signal repeater, the output of which, in turn, is connected to the second input of the adder - the operational amplifier (12). The output of the summing operational amplifier (12) is connected to the output connector (14), which is connected to the vertical scan channel of an external storage oscilloscope or recorder.

Additional view A (Fig. 2) shows the axes of the Hall sensors sensitivity. Hall sensor (7), designed to measure the magnitude of the magnetizing field, is located so that the axis of its maximum sensitivity is in the horizontal plane - parallel to the axis of the Helmholtz rings (1). Hall sensors (4) and (5) are placed in such a way that the axes of their maximum sensitivity are in the vertical plane and, at the same time, as close as possible to the edges of the test sample of a thin magnetic film.

The device works as follows. The signal from the low frequency current generator (2) (Fig. 1) goes to the Helmholtz rings (1), which create an alternating magnetic field. Inside the Helmholtz rings (1) is a printed circuit board (3) with radio components, including Hall sensors (4), (5) and (7). The direction of the alternating magnetic field created by the Helmholtz rings (1) (Fig. 2) coincides with the direction of maximum sensitivity of the vertically located Hall sensor (7), the output signal from which is fed to the operational amplifier (8), which acts as a low-pass filter, and then to the output connector (9). Thus, the signal at the output connector (9) is directly proportional to the magnitude of the magnetic field reversing the sample (6) under study. From connector (9) the signal is fed to the horizontal scan input of the storage oscilloscope or recorder. Hall sensors (4) and (5) are located in such a way that the axes of their maximum sensitivity are oriented perpendicular to the direction of the magnetic sweep field created by the Helmholtz rings (1). Thus, in the absence of the test sample (6), the signals at the outputs of the Hall sensors (4) and (5) are not observed. The investigated sample (6) of a thin magnetic film is placed symmetrically above the horizontally located Hall sensors (4) and (5). During the magnetization reversal of the sample under study (6), a vertical component of the magnetic induction vector appears, which is recorded by Hall sensors (4) and (5). With a symmetrical arrangement of a homogeneous test sample (6) of a thin magnetic film above the Hall sensors (4) and (5), signals appear at their outputs that are equal in magnitude and opposite in sign. The output signal of the Hall sensor (4) goes in series to the operational amplifiers (10), (11) and (12), which act as a voltage follower, low-pass filter and adder, respectively. The output signal from the Hall sensor (5) is fed in series to the operational amplifiers (13) and (12), which act as a voltage follower and adder, respectively. Thus, antiphase useful signals are supplied at the inputs of the adder - operational amplifier (12), which are added modulo and fed to the output connector (14). From connector (14), the signal is fed to the vertical scan input of the storage oscilloscope or recorder. A hysteresis loop is observed on the oscilloscope screen, which determines the main magnetic characteristics of the sample under study (6).

Experimental studies of the inventive looplescope for the study of thin magnetic films have shown that, in comparison with a device of a similar purpose (prototype), the inventive device is much easier to manufacture, since it does not have multi-turn coils of the sensing element, there is no signal integration unit, and to create a magnetizing field can be used any external sources of alternating magnetic field.

The loop for studying thin magnetic films can be used in cases where there is a need to measure, along the hysteresis loop, such physical parameters of thin-film samples as magnetic moment, saturation magnetization, residual magnetic moment, remanent magnetization, coercive force, magnetic anisotropy field.

Claims (1)

A loop for studying thin magnetic films, containing a system for the formation of a magnetizing field, an oscilloscope for observing the hysteresis loop and recording its parameters, characterized in that two Hall sensors are used as a sensitive element, located under the test sample of a thin magnetic film in such a way that their axes are maximal sensitivities are oriented perpendicular to the direction of the magnetizing field and perpendicular to the plane of the thin magnetic film, and the signal of one of the Hall sensors is inverted and summed with the signal of the second Hall sensor, and the third, additional Hall sensor, is used to measure the magnitude of the magnetizing field.

Images