RU2134417C1 - Process measuring magnetic susceptibility of oxide compositions and salts in liquid and solid phases - Google Patents

Abstract

FIELD: measurement technology. SUBSTANCE: process measuring magnetic susceptibility of oxide compositions and salts in liquid and solid phases is related to field of physical methods of study of magnetic characteristics of substance used in high and increased temperatures. As distinguished from existing methods proposed process makes it possible to measure magnetic susceptibility by contact method both in liquid and solid phases. With this in mind pole pieces are placed into melt of sample and inductance L of circuit " POLE PIECES-SAMPLE-MELTING POT " is measured with sample being cooled to hardening. Then inductance L_o of circuit POLE PIECES-AIR- MELTING POT " is measured in same temperature interval under same cooling rate. Magnetic susceptibility is found by formula X=L/L/L_o-1. In this case there is no necessity of formation of significant magnetic field between pole pieces and, in consequence of it, no need in usage of bulky members of structure such as frame of electromagnet, excitation coils, storage battery, etc. Besides, the process makes feasible to replace measurement of mechanical value - force and to abandon by that usage of range lengtheners and signal amplifiers. EFFECT: simplified and efficient measurement of magnetic susceptibility of oxide compositions and salts. 3 dwg

Description

 The invention relates to the field of physical methods for measuring the magnetic characteristics of substances, and more specifically to those that are used at elevated and high temperatures.

 The methods currently used to study magnetic properties measure some quantity, most often mechanical (force) directly related to the magnetic susceptibility of the substance χ, which is a characteristic that depends on the temperature and state of all the electrons (free, valence, internal) of a given substance, as well as its state of aggregation.

 These methods are based on measuring the force that acts on a sample placed in an inhomogeneous magnetic field. As a means of measurement, magnetic gauges are used. The test sample of a cylindrical shape with predetermined geometric parameters is placed in a container, for example, in a crucible and suspended on a sensitive balance to the balance. The container with the sample is located between the poles of the magnet, creating a powerful inhomogeneous field (strength of the order of 10,000 Oe). If the sample is paramagnetic, then its energy inside the magnetic field decreases, and therefore a force appears that draws the sample into the field. If the sample is diamagnetic, its energy is less outside the field, and therefore some force pushes it out of the field. This force is proportional to receptivity; therefore, determining the position of the balance, one can find χ.

 The literature also describes a method for measuring the magnetic susceptibility χ (V. M. Glazov, S. N. Chizhevskaya, NN Glagoleva Liquid semiconductors. M .: Nauka, 1967, p. 29), which consists in measuring the ponderomotive force F acting per sample in an inhomogeneous magnetic field. Moreover, for small sizes of the sample, the field gradient is neglected, as a result of which the ponderomotive force is proportional to the magnetic susceptibility with constant mass of the sample. This allows measurements of the magnetic susceptibility by the relative method, i.e. F = kχ, where k is the instrument constant determined on a sample with known magnetic susceptibility.

 Known methods for measuring the magnetic characteristics of substances are very complicated in technical execution and are essentially non-contact, i.e. the influence of a magnetic field generated by a magnet with pole tips of a special shape is not carried out directly on the sample, but through a system of heat-insulating screens, the surface of the heater, or the circuit of the inductor, which leads to a distortion of the results. In addition, it is necessary to insulate the pole pieces and the magnet in order to preserve its magnetic properties, which is especially difficult at high temperatures. At the same time, the distance between the studied sample and the poles of the magnet is very significant, so there is a need to form a field with a strength of at least tens of thousands of e. And, finally, a common drawback of these methods is to give the samples the correct geometric shape.

The closest in technical essence to the claimed should be considered a method of measuring the magnetic susceptibility of solid and liquid metals, including the operation of creating an external magnetic field, placing the pole pieces of the magnet near the outer surface of the sample in the crucible, heating the sample, and measuring the result of the interaction of the magnetic field with the sample ( P.P. Arsentiev, V.V. Yakovlev, M.G. Krasheninnikov et al. Physicochemical Methods of Investigation of Metallurgical Processes (Moscow: Metallurgy, 1988, p. 129). The described method has several advantages, which are as follows:
- measurement of magnetic susceptibility is carried out by the absolute method without the use of calibration substances;
- the ability to accurately determine the area in which the magnetic field gradient is constant.

However, the existing method is only effective in measuring the magnetic susceptibility of metals, for example Fe, Co, Ni, Zr, Pt. This is due to the fact that the absolute value of the magnetic susceptibility of metals, both diamagnetic and paramagnetic, is significantly higher than that of the corresponding salts and oxides. Thus, the magnetic susceptibility of Fe, Co, and Ni below the Curie temperature reaches several tens of thousands. Diamagnets: CO ₂ χ = -5.3 • 10 ^-6 , H ₂ O χ = -9.0 • 10 ^-6 , Ag χ = -26, Bi χ = -170 and paramagnets O ₂ χ = 1.8 • 10 ^-6 , Al χ = 21 • 10 ^-6 , Pt χ = 300 • 10 ^-6 . Therefore, the effect of changing the force acting on the sample is manifested more significantly. Due to the fact that the pole tips of the magnet are located far from the sample, it is necessary to generate, between them, a powerful field with a strength of 20-25 KE and use bulky coils and battery batteries to power the massive body of the electromagnet.

 In other words, an inductor, a heater, heat-insulating screens and a crucible located between the pole pieces of the magnet create a shielding effect and prevent the interaction of the magnetic field with the substance under study.

 In addition, the operation of measuring the force acting on a sample in a magnetic field using compensation microbalances is fraught with a number of difficulties due to the presence of convection gas flows circulating in the heater space and destabilizing the measurement system throughout the entire experimental cycle, as well as the additional use of range extenders for compensation for a significant change in strength, or vice versa, the strengthening of a weak change in force. Those. there is a mutual conversion of a mechanical quantity into an electric quantity. Therefore, it seems a natural step to exclude the mechanical measurable quantity and to operate only with the electric one.

 The noted disadvantages allow us to conclude that this method can hardly be successfully used to measure the magnetic susceptibility of oxide compositions and salts.

 The aim of the present invention is to reduce the intensity of the electromagnetic field acting on a sample of oxides and salts, as well as the exclusion of the measurement of mechanical quantity - force.

This goal is achieved by the fact that in the known method of measuring magnetic susceptibility, including the operation of creating an external magnetic field, placing a crucible with the sample in it, heating the sample and measuring the result of the interaction of the electromagnetic field with the sample, the sample is heated until it is completely melted, the pole pieces are placed in the sample melt , measure the inductance of the circuit "pole pieces - sample - crucible" - L, while cooling the sample to solidify, then measure the inductance of the circuit "pole tips iki - Air - crucible "- L _o in the same temperature range and at the same cooling rate, and the magnetic susceptibility χ defined formula but χ = L / L _o - 1.

Another difference is that the placement of the pole pieces in the sample is carried out at the time of melting of the sample, or at any other temperature T exceeding the melting temperature of this sample T ₁ , i.e. in the liquid phase.

The authors found that when the pole pieces are immersed in the melt at a distance between the pole pieces of ~ 1 cm and their diameter is ~ 0.5 mm, the current through the measurement object does not exceed 75 - 750 • 10 ^-3 A. The field strength created by it in the first approximation is H = i / 2πR = 750 • 10 ^-3 /2•3/14•0.01 ~ 1.2 A / M = 1.2 • 10 ³ / 4π = 100 Oe, which is one to two orders of magnitude less than the methods described in the literature.

 Placing the pole pieces in the sample provides direct interaction of the electromagnetic field with the substance, bypassing all possible obstacles that are structural elements: heater, lining, screens and the wall of the crucible in which the sample is located.

 The advantage of the option of placing the pole pieces in the sample in the liquid phase is due to the fact that most of the oxides and salts are crystalline under normal conditions, therefore, the connection of the pole pieces to the sample is difficult to press in and maintain reliable electrical contact during the measurement time. Whereas, the placement of the pole pieces in the liquid phase allows reliable contact with the substance in the solid phase, during its crystallization, since the pole pieces are pressed into the sample and carry out measurements both in the liquid and in the solid phases.

The physical essence underlying the proposed method consists in the following. Experience shows that the inductance of any circuit depends on the properties of the medium in which it is located. If L _o is the inductance of a certain circuit in vacuum (either in air or in an inert atmosphere), and L is the inductance of the same circuit in a homogeneous substance (in our case, in the sample under study), then the ratio L / L _o = μ, called the magnetic permeability, characterizes the magnetic properties of a substance, it depends on the type of substance, its state (for example, temperature). Since the magnetic susceptibility is determined by the relation χ = μ-1, χ is positive for paramagnets and negative for diamagnets.

 FIG. 1 illustrates the implementation of the proposed method. Heating device 1. A crucible with a sample 2. A test sample 3. Pole tips 4. A measuring device, such as an AC bridge 5.

Thus, the use of the proposed method for measuring the magnetic susceptibility of oxide compositions and salts in solid and liquid phases provides, in comparison with known methods, the following advantages:
- ease of use and structural design;
- a decrease in the intensity of the generated electromagnetic field acting on the sample by at least one to two orders of magnitude, which eliminates complex and bulky structural elements (electromagnet, field coils, batteries, etc.);
- eliminate inconvenient mechanical measurements at high temperatures
- force and device for its fixation - scales;
- to measure the magnetic susceptibility by the contact method in both solid and liquid phases without the use of reference substances over the entire temperature range of interest.

Example 1. Measure the magnetic susceptibility of a solution of iron oxides FeO and Fe ₂ O ₃ , which are antiferromagnets. The melting point of this composition, in equilibrium with the air gas atmosphere, is equal to 1590 ^o C. Sample 3 is placed in a refractory crucible 2, for example platinum and heated using a resistance furnace 1 to a temperature of 1610 ^o C and kept with it for some time. Between the pole pieces 4 of refractory inert metal create a magnetic field of low power and enter the pole pieces into the melt to a predetermined depth. After that, the inductance L of the circuit "sample - pole pieces - crucible" is measured, with continuous slow cooling, up to room temperature. As a result of these operations, a functional dependence of the inductance of the circuit "sample - pole pieces - crucible" L = f (T) is obtained. To obtain the desired dependence of the magnetic susceptibility of the sample on the temperature χ = f (T), the inductance L _o is measured in the absence of the sample, that is, the inductance of the pole tips - air - crucible circuit in the same temperature range of 20 - 1610 ^o C and at the same cooling rates L _o = f (T). And, finally, taking the ratio L / L _o = μ and subtracting 1 from it, we obtain the desired functional dependence of the magnetic susceptibility of the sample on temperature L / L _o - 1 = μ - 1 = χ (T) (Fig. 2). At the same time, there is no need to use a reference substance and to carry out calibration with it over the entire temperature range of interest. The figure shows the temperature of the magnetic transformation (from the paramagnetic region to the antiferromagnetic) 6 and the phase transition from the liquid phase to the solid 7.

Example 2. Measure the magnetic susceptibility of potassium bromide KBr, which is a typical diamagnet. The melting point of which is 734 ^° C. The sequence of operations is the same as in Example 1. The measurement results are shown in FIG. 3. As can be seen from the presented results, the magnetic susceptibility of potassium bromide is practically independent of temperature either in the liquid or in the solid phase, which is quite natural, since the magnetic moment of the KBr molecule is zero. The phase transition from liquid to solid 8 is also quite pronounced.

 The inductances in Examples 1 and 2 were measured using an P5083 AC bridge.

Claims (1)

A method for measuring the magnetic susceptibility of oxide compositions and salts in liquid and solid phases, including creating an external magnetic field, placing a crucible with a sample in it, heating the sample and measuring the result of the interaction of the magnetic field with the sample, characterized in that the sample is heated until it is completely melted, pole tips in the melt of the sample, measure the inductance of the circuit pole tips-sample-crucible - L when the sample is cooled to harden, then measure the inductance of the circuit nicks - Air - crucible - L at _about the same temperature range and at the same cooling rate, and the magnetic susceptibility χ is given by: χ = L / L _of - 1.

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