Electro-physical Properties of Super-thin Basalt Fiber Chemically Modified by Hydrochloric or Sulphuric Acid ()
1. Introduction
Natural basalt rock is a porous aluminum-silicate hard material having volcanic origin. The processed basalt samples are used in industry: for construction, water drainage, insulation and so on [1-3]. After it was made possible to produce continuous basalt fibers from rock [4-6], their application was expanded as heatand soundinsulators [7-9]. Besides, due to their high thermal stability, ecological compatibility and inertness with relation to the majority of aggressive materials, basalt fibers are used for filtering of industrial gas emissions without preliminary cooling [10].
STBF with diameter of a few microns are 1D crystals and possess all features of nanocrystalline materials (1D crystal, quantum dimensional effect) being of scientific and practical interest. Hence, these materials are interesting from the point of view of their electro-physical properties too and it is necessary for more systematic study of mentioned parameters, as well as their dependence on various external factors such as temperature, humidity, chemical modification, etc. Such works are scarce in scientific literature and available papers only present research on basalt rocks [11].
This paper for the first time presents electro-physical and thermal characteristics of super-thin basalt fibers (STBF) prepared from Armenian basalt rocks with average diameter of less than 10 mm after treatment by hydrochloric or sulphuric acid.
2. Experimental Materials and Procedures
The samples of STBFs were prepared using standard technology [4-6] on Armenian basalt rocks (near Abovyan city). For technical applications STBFs are manufactured in the form of layered wool with packing bulk density D = 0.25 g/cm3 that is considerably lower than the real fiber density (DR = 2.7 - 2.8 g/cm3) [4,5,12]. For measurements, pieces of the wool were cut into flat rectangular felt having an area from 0.7 cm2 to 1.5 cm2. Then these samples were placed between two copperplated laminated bakelite slabs. The same slabs were used as electric probes, to which ac or dc fields were applied. Probes with the samples were attached on a plastic holder, specific resistance of which (>1017 Ω·cm) was higher than that of the measured materials.
As a result of acid treatment of STBFs their structural and, hence, many physical properties may change. The samples were dried to constant weight during 8 hours at temperatures 115˚C - 120˚C. Initial sample after leaching and drying loses 51.5% of its weight. According to the results of chemical analysis, the end-product has the following structure: SiO2-95.56%, Al2O3-2.25%, Fe2O3-0.8% (amounting to 98.61%).
Chemically modified samples in hydrochloric or sulphuric acid are referred as samples 1 and 2, correspondingly. For these samples, specific electric resistance for direct and alternating current and then, dielectric parameters and were measured. The specified parameters were measured at the temperature from 100 K to 365 K and relative humidity of air not more than 50%. Parameters, and for basalt fibers were measured by means of a precise bridge for measurement of capacities (TESLA BM 400 G). This bridge enables to measure loss tangent to 0.1 and capacity accurate to ±1% at a fixed frequency of 800 Hz. To measure higher, another transformer bridge circuit was developed to measure to 50 at frequencies from 200 Hz to 1 MHz. Using this device, it is possible to measure active and reactive components of signals from the investigated samples with accuracy up to ΔG = 10−8 Ω−1 and ΔC = 0.05 pF, correspondingly. Calibration of the device and accuracy testing of the measured objects were carried out for known values R and C, which were previously measured using impedance meter BM 507 and capacity meter BM 400 G, correspondingly.
The value of was determined from expression, where is the capacity of a flat capacitor with dielectric and capacity of this capacitor without dielectric. Parameter was calculated from formula and was determined by formula, where is dielectric constant, is angular frequency of the electric field [13, 14]. Specific resistance of the sample for direct current was determined by dual probe method using formula, where is a direct current voltage applied to the sample, is a current passed through it, is an effective area of the sample, and is an effective thickness of the sample in the current direction. For our samples ≤ 1 mm. Resistance measurements () of the sample for direct current were carried out using electrometric voltmeter V7-30 which allows measurements of up to 1018 Ω.
The weight of investigated samples varied in the range from 25 to 40 mg. Relative error in all types of the fulfilled measurements did not exceed 5%.
3. Experimental Results and Discussion
The results of the effect of hydrochloric (HCl) or sulphuric acid (H2SO4) processing on the electro-physical properties of super-thin basalt fiber (STBF) are presented in Figures 1-6. It is seen from Figure 1 that e'(Т) and e''(Т) curves reveal a maximum corresponding to minimum of ρac(Т) for both samples. For the sample 2 minimum is shifted towards higher temperatures by 30 degrees (Figure 2). In this case specific electrical resistiv-
Figure 1. Temperature dependence of dielectric permeability ε' and dielectric loss ε" coefficients (at frequency 1 kHz) for the chemically modified STBF samples by sulphuric acid.
Figure 2. Temperature dependence of specific electrical resistivity ρac for the frequency of 1 kHz of alternating current field for the chemically modified STBF samples by sulphuric and hydrochloric acids.
ity ρac of the sample 2 at temperature 300 K is approximately 3 times higher than that for the sample 1. At the same time this difference for ρdc varies from 3 to 4 depending on the time passed after switching on of dc electric field (Figure 2). The presence of maxima on e'(Т) and e"(Т) curves (see Figure 3) or minima on ρac(Т) curves for both samples (Figure 2) means that depending on temperature at least two competing mechanisms could act. It is confirmed by the presence of two strongly distinguishing slopes in temperature intervals from 100К to 200 K and from 200 K to 300 K on both e'(Т) and e''(Т) curves (Figure 1), and ρac(Т) curves (Figure 4). The slopes presented in the figures are apparently related to the presence of weakly connected and strongly connected
Figure 3. Dependence of specific electrical resistivity for field of samples 1 and 2 on duration of the applied direct current field (Тmeas = 20.4˚C, relative air humidity of 49.9%, the packing density of the sample here is the same as in Figures 1, 2 and 4: D = 0.5 g/cm3).
Figure 4. Frequency dependence of specific electric conductivity for alternating current (ρac) at T = 30˚C for the chemically modified STBF samples by leaching using sulphuric and hydrochloric acids.
dipole water molecules. Decreasing character of ρac on frequency of the applied field (see Figure 4) shows that in both samples the mechanism of dipole polarization [13,14] takes place. According to [12], starting from 40˚C super-thin basalt fibers reveal a remarkable water loss that causes sharp decrease of e' and e" or increase of ρac and occurrence of maxima and minima on temperature dependences of electric characteristics (Figures 1 and 2). On the other hand, it is shown in [12] that the samples after processing in sulphuric acid reveal higher adsorbing ability for water vapor. Besides, the fraction of strong bounded water molecules is higher in this sample. This means that water begins considerably evaporate at higher temperature thus causing the mentioned shift for the Sample 2 with corresponding extreme values of 30 degrees towards higher temperatures in comparison with the Sample 1.
In favour of higher water content testifies the fact that for the Sample 2 the ρac decreases faster depending on frequency of alternating electric field, than for the sample 1 (Figure 4). This fact correlates with results of dependence of ρdc on duration of the action of direct electric field for both samples (Figure 3). It is seen that at reduction of the action of direct electric field (which is equivalent to application of high frequencies of alternating electric field) the ρdc values for both kinds of leached (hydrochloric and sulphuric acids) samples become nearer.
The results of the influence of packing density on the electro-physical properties of STBF samples are presented in Figures 5-6. It is seen from Figure 5 that for the chemically modified STBF samples using sulphuric acid the parameter ρac decreases gradually with increasing of packing density. This decrease is by factor of 3 when the packing density increases from 0.5 g/cm3 to 1 g/cm3. While for the sample modified using hydrochloric acid the parameter ρac decreases by factor 3.6 at the same conditions (see in Figure 5). However the results of investigations with direct current field application showed that the curves of ρdc depending of packing density have non monotonous character and the observed changes for Sample 2 is 2 times while for sample 1it is almost 14 (Figure 6). Note that non monotonous dependence of filtering ability of the nanofiber system on packing density was observed in recent publication [15]. The reason of the reduction of ρac and ρdc for both samples may be in increasing of mechanical hardness after their chemical treatments which may increase the packing density of fibers and hence, a reduction of the distance between them causing easy the charge transfer between fibers and, in result, decreasing of ρac and ρdc.
The above mentioned results allow assuming that after treatment of STBF by sulphuric acid these samples be-
Figure 5. Dielectric permeability e' and dielectric loss e" coefficients (at frequency 1 kHz) depending on packing density for the chemically modified STBF samples using sulphuric acid.
Figure 6. Specific electrical resistivity ρdc for direct electric field depending on packing density for the STBF samples chemically modified using hydrochloric (a) and sulphuric (b) acids. The measurements were carried out after 5 second switch on the d-c electric field.
come more stable to the external influences. In particular it is expressed in low sensitivity of their electrophysical parameters to the temperature change, packing density and rapid achieving of final value of ρdc after switch on direct field (see Figures 2, 3, 5 and 6). Note that this time is about 200 s for the sample 2 while for the sample 1 this time is significantly higher.
4. Conclusions
Thus the main results on research of the influence of acid treatments on the electrophysical parameters of STBF should be concluded as follows:
1) Electro-physical parameters of samples after sulphuric and hydrochloric leaching depending on temperature show a peak (or minimum). The appearance of the peak (or minimum) is conditioned by variation of dipole mechanism of polarization, caused by thermal activation of water molecules and further escape from the sample. And its strong temperature quenching is conditioned by high capability of absorbed water.
2) The results showed that specific electrical resistance on alternating current in STBFs, leached both in sulphuric and hydrochloric acids, depending on their packing density, qualitatively shows similar behaviour: it decreases stepwise, but in first case this decrease is quite weak. However, the sensitivity of specific electrical resistance on direct current, compared to variation of packing density is a few times more in sample, treated with hydrochloric acid.
5. Acknowledgements
This work was supported by International Science and Technology Center (ISTC) Project No. A-1605. The authors are grateful for this assistance.