DE1216425B - Device and method for determining low magnetic moments of weakly magnetic samples - Google Patents

Description

Apparatus and method for determining low magnetic levels Moments of weakly magnetic samples The determination of lower remanent magnetic Moments of weakly magnetic samples are of particular importance, e.g. for volcanic ones and sedimentary rocks on which this determination requires the conduct of investigations for more precise recognition of the paleogeographical and paleoclimatological conditions under which these rocks were formed. There will also be a allows more careful evaluation of the results of magnetometric soil surveys as well as determining the direction of magnetization of drill cores in the laboratory, causing the strike and fall of the rock strata penetrated by the borehole can be determined.

So far, devices for determining such lower remanent magnetic Moments on the order of 10-7 C.G.S electromagnetic units per Cubic centimeters lies, known only in the form of apparatuses, as to their essentials technical components are very sensitive. These are astatic Magnetometer of a special construction with a torsion suspension and a very light one Movable magnet system, made up of two exceptionally carefully astatic Permanent magnets. The disadvantage of these devices is that the production such a movable magnet system difficult and the determination of the magnetic Moments cumbersome due to the calculations and operations to be carried out later is.

The development of Vorn.htungen should also be mentioned here, where the voltage is measured in a coil by rotating the one placed in front of it Samples is generated.

In the device according to the invention, instead of the system, the system becomes more astatic Permanent magnets used astatic coils, and the torque applied to the in one uniform magnetic field by means of a torsion band suspended sample becomes effective is measured by magnetostatic methods.

Experiments carried out for this purpose led to the construction of devices with a sensitivity not exceeding 10-6 electromagnetic C.G.S. units per cubic centimeter.

With the device according to the invention, there are thus low levels of magnetic Moments by measuring the placed in a uniform magnetic field Specimen acting force couple determined.

The device according to the invention is characterized in that a the evacuated glass vessel containing the sample in a vessel filled with water on one attached to the bottom of the latter the buoyancy of the glass vessel slightly Torsion tape subjected to tensile stress is suspended for the purpose of recording the deflections a mirror on photographic recording paper in a manner known per se carries, and that the vessel filled with water in another vessel with 0.5 to 5.0 ° C colder water is arranged, and in order to produce the uniform Magnetic field around the sample a pair of coils with a horizontal axis and in which is arranged rotatably through the same laid horizontal plane.

When using the device according to the invention is on the movable System of the same exerted a torque when in the area of the specimen a size and spatial position constant, uniform magnetic field is applied.

The light spot to be tracked with the device according to the invention is arranged perpendicularly by reflection of a light beam at the mentioned Mirror generated. The movement of the light spot can also take place at certain time intervals are marlciert on a scale so that curves are obtained which are photographed are similar. The glass vessel containing the sample is cylindrical, tightly closed and not magnetic. The disturbing vibrations of the moving system are by the complete immersion of the torsion band and the glass vessel containing the sample steamed in a water-filled, transparent, cylindrical container.

For the determination of remanent magnetic moments of weakly magnetic ones Samples with the device according to the invention will be a measurement in two or more Phases carried out in which the directions of the field are different and known are. This becomes the result of a recording phase according to size and spatial Position constant magnetic field expediently after a period of time that is a half-oscillation period of the movable organ, reversed several times in its direction. The record the position of the light spot begins at a point in time that is at least equal to the duration the period of natural oscillation of the moving system before the time of mooring of the magnetic field: Each recording phase corresponds to a certain from one stage to another different direction of the applied magnetic field compared to a reference mark applied to the sample. Under "reference mark" an arrow line attached to the specimen is understood to refer to the Direction of the remanent magnetic moment is to be determined. So corresponds z. B. for paleomagnetic studies this marking is usually the magnetic one or geographic north, while on samples from drill cores usually the direction of fall of the layers is noted.

Furthermore, a demagnetization takes place after each phase recording the sample made in such a way that the sample in the previous Phase is eliminated by the magnetization imparted to the uniform magnetic field. This magnetic "cleaning" of the sample is carried out by means of a practically sinusoidal magnetic alternating field, the amplitude of which changes over time in the same Direction is evenly reduced and its initial amplitude during the respective Recording corresponds to applied continuous constant magnetic field strength.

It is known that a light spot is shifted over time visible on a scale with the help of a light beam reflected by a mirror close.

The part of the invention relating to such a "light pointer" However, the device should not be placed under protection by itself. According to »Microtecnic <», Vol. VIII, pp. 338 to 341 (1952), an apparatus based on the principle of the mirror galvanometer is based (cf. also Microtecnic, Vol. VI, p. 197 [1952]) for magnetic measurements This apparatus, which, in addition to other components, has a permanent magnet, a frame with a coil, an axle and an ammeter is considerably less simply constructed as the device according to the invention, and from the a. a. O. stated It is not evident from measurement experiments that the aforementioned known apparatus does the measurement magnetic moments as small as the device according to the invention. A deflection of a reflected light beam is also caused by that from the German Patent 593 453 known measuring device for recording and recording the magnetic Properties of strip-shaped samples caused, however, this device requires one Field measuring system and an induction measuring system as well as a magnetization coil, and in the preferred embodiments are to direct the light beam either two mirrors and a prism or a total of three mirrors are necessary. About the accuracy or sensitivity of this device are in the patent in question Information provided. With the device known from German patent specification 700 048 are magnetic quantities, especially the coercive force, using a astatic magnet system can be measured inside a coil arrangement. As an an example the measurement of a coercive force of 0.02 Örsted is mentioned here. From this Indication is to be concluded that with the mentioned known device not so low magnetic moments can be measured as with the invention Contraption. Finally, there is a device from German patent specification 171 674 known for testing magnets, in which the braking force of the magnets is relative metal masses moved towards them - measuring organ from one rest position to another Brings rest position. Using such a device to determine less of magnetic moments, however, apparently nothing has become known.

The method and apparatus according to the invention are set out below on the basis of an exemplary embodiment and with reference to the drawings to be discribed.

Fig. 1 shows the basic structure of a device according to the Invention in a schematic representation. The device comprises a mobile system, which from the sample 1, the tightly closed glass vessel 2 and the one on a torsion band 4 suspended mirror 3 consists. Both the torsion device or the rotary balance as well as the entire movable system are completely in a vessel filled with water 5 immersed. The weight of the volume of water displaced by the moving system is slightly larger than its own weight, so that a tensile force is exerted on the torsion band of about 1 g attacks.

The rock sample is arranged in the middle of a coil system 6, which is used to generate a homogeneous, horizontal magnetic field in the area of the Sample is used and can be rotated around the sample with the aid of a device 7. The moving system is rotated by means of the guide cover 8, part-9 and the rods 10. When removing the cover 8, together with the parts 9 and the rods 10, the torsion band is supported by a bracket 11 and a locking pin 12 secured.

The position of the moving system is recorded photographically, wherein a light beam supplied by a light source 13 reflects off the mirror 3 and projected in the form of a spot of light onto photographic paper, which is wound on a drum 14 located 1 m from the mirror and is driven by an electric motor or a clockwork.

The moving system (and thus the light spot) can thereby be stabilized be that the water-filled container 5 is arranged in a further container 15, which is also filled with water. The temperature of the water in the latter Container 15 is 0.5 to 5 "C lower than the temperature of the water in the container 5. The directed convection flow generated in the container 15 in this way ensures better stabilization of the moving system than an omnidirectional flow that occurs when using a thermostat system and would not allow sufficient stabilization.

The measuring device according to the invention operates as follows: If from the coil system does not generate a magnetic field, the light spot remains immobile, so that a straight line is formed on the photosensitive paper. When through Feeding the coil system with a current of known magnitude a field H of the order of magnitude of 1 to 15 Gs is generated, a torque is applied to the sample, which the field H, the magnetic moment P of the sample and the sine of the field H with the magnetic moment P is proportional to the angle formed. When reversing of the current acts a torque of the same magnitude, but in the opposite direction, to the test. The current is reversed several times in a row with the help of a reversing switch, at time intervals which are half the oscillation period of the moving system.

So there is an overall shift on the photosensitive paper of the light spot recorded, which is proportional to the moment P and H.

About the possible effect of magnetization on the direction of the field H must be demagnetized with one of the applied DC field strength starting from decreasing alternating current, by means of a regulating transformer Av and a switch 1.

Then the system of the coils having a horizontal axis rotated by a certain angle (i.e. 90 °) and then the recording in the same way repeated. On the basis of the two records, a simple Calculation to determine the size and direction of the remanent magnetism of the sample (the component in the horizontal plane) with respect to one on the sample attached and aligned according to the known positions of the coil system be performed.

By means of the method described above and also described device can have a remanent magnetism on the order of 10-7 electromagnetic C.G.S. units per cubic centimeter and below determined will.

The F i g. 2 and 3 are examples of records as used for certain rock samples were obtained.

The first curve sheet (FIG. 2) relates to a marl with a calculated remanent magnetism of 6 - 10-7 electromagnetic C.G.S. units per cubic centimeter, while the second curve sheet (Fig.3) is on a tone with a calculated remanent magnetism of 4-10-7 electromagnetic C.G.S. units per cubic centimeter.

The times at which a field H is created are shown in these curves with A, Al and A2, the times of the creation of a field H in opposite directions Direction with B, B1 and B2 and the time of switching off the fields with 0.

The direction of field H is for curves I, II and III in F i G. 3 each different, with both the angle between the directions 1 and II as well as the angle θ between the directions I and III is known. The direction of magnetization is obtained by resolving the following equation in pairs system by means of known analytical or graphic methods: dI = AMH sinus, dII = AMHsin (ß-, dIII = AMH sin (dos), where dI, dII and dIII can be seen from the graphs Distances, H is the applied magnetic field, whose value is determined by the strength of the coils flowing current and is determined by the coil characteristics, and A is a constant, the value of which is determined experimentally, and of the constant of the torsion band, the distance between the mirror and the photosensitive Paper and the degree of damping of the vibrations of the system depends.

The method and apparatus according to the invention offer the following Advantages: Simplicity in measuring and calculating the results; fine response and great accuracy; no construction difficulties because of the device can be created with extremely simple technical means; lesser Cost compared to the known devices.

Claims (4)

Claims: 1. Device for determining low magnetic Moments of weakly magnetic samples by measuring the moments in a uniform A pair of forces acting on the sample arranged in a magnetic field, thus no indication e t that an evacuated glass vessel containing the sample (2) in one with water filled vessel (5) to one attached to the bottom of the latter, due to the buoyancy of the glass vessel (2) slightly stressed torsion band (4) suspended is for the purpose of recording the deflections on photographic recording paper carries a seal (3) in a manner known per se, and that the filled with water Vessel (5) arranged in a further vessel (15) with 0.5 to 5.0 ° C colder water and where a for the purpose of generating the uniform magnetic field around the sample Coil pair (6) with a horizontally extending axis and in the one laid through the same Horizontal plane is rotatably arranged. 2. Method for determining remanent magnetic moments weak magnetic samples by measuring the exposure to them in a uniform magnetic field arranged sample after acting force couple using a device Claim 1, characterized by a measurement taking place in two or more phases, in which the directions of the field are different and known. 3. The method according to claim 2, characterized in that to achieve a recording phase the constant magnetic field in terms of size and spatial position in each case after a period of time that corresponds to a half-oscillation period of the movable organ is reversed several times in its direction. 4. The method according to claim 2 or 3, characterized in that after each phase recording demagnetization of the sample is carried out in such a way that the sample, if necessary, in the preceding Phase is eliminated by the magnetization imparted by the same magnetic field. Considered publications: German Patent Specifications No. 700048, 593 453, 171 674; "Microtecnic", Vol. VIII (1952), No. 6, pp. 337 to 343, Vol. VI (1952), No. 4, pp. 197 to 203.