Production of Ca 2 AlNbO 6 Ceramics and Study of Their Stability in Crude Petroleum for the Conservation of Metallic Sensing Elements Used in Petroleum Extraction

In the present work a niobium based complex cubic perovskite oxide Ca2AlNbO6 ceramic was produced, characterized and studied its stability in crude petroleum environment for inert ceramic embedding for temperature sensors used in petroleum extraction. Ca2AlNbO6 ceramic powder was prepared through thermo-mechanical processing. Structural characteristics of calcined material was investigated by powder X-ray diffarctometry, which presented a single phase complex cubic perovskite structure with lattice parameter a = 7.6599 Å. Compacted discs of Ca2AlNbO6 ceramics were sintered in the temperature range 1250 ̊C 1350 ̊C during 24 hours in ambient atmosphere. Microstructure of the sintered ceramics was studied by scanning electron microscopy and mechanical behavior was studied by Vicker’s microhardness testing. Ca2AlNbO6 ceramics sintered at 1350 ̊C presented best results in terms of microstructural homogeneity and mechanical hardness. Therefore these sintered ceramics were submerged in crude petroleum for 60 days. Ceramics were taken out from the petroleum periodically and subjected to structural, microstructural and mechanical characterizations. Results showed that ceramics submerged in crude petroleum did not suffer any change at any stage of submersion. These characteristics make this material suitable for inert ceramic embedding for sensors used in petroleum extraction.


Introduction
Nowadays, there is an increasing demand for sustainable materials and systems to operate in hostile environments such as high temperature or chemically aggressive environments of petroleum extraction industry.In petroleum extraction, different types of sensors are required to monitor temperature, pressure and other vital parameters in the petroleum wells.These sensors work in extremely hostile environment.In case of temperature sensors, normally, sensing elements are metals Pt, Nb etc., which are highly sensitive to environmental conditions.Accordingly, these sensors need to be embedded in materials highly inert to petroleum extraction environment.Ceramics are parts of a broad class of materials whose extremely vast characteristics such as: high thermal capacity, resistance to corrosion, fact that they may be insulating, conducting or superconducting, they have magnetic properties or absence of magnetism, and to be hard and resistant but fragile, make them interesting for various technological applications [1][2][3].
Study of advanced ceramics makes it possible to de-velop new technologies, which could be inaccessible with conventional materials and also to substitute scarce materials.Their cast of production turns to be more viable than those of metals and metallic alloys, as they are lighter materials and stable at higher temperatures [4,5].Earlier research works in 1950 and 1960's [6,7] identified a large group of ceramics, which have the basic ABO 3 perovskite structure or a small distortion of that structure.These complex perovskite oxides generally have the formula A 2 BB'O 6 or A 3 B 2 B'O 9 and result from the ordering of B and B' cations on the octahedral sites of the basic perovskite unit cell.Due to the increased complexity of the unit cell, a large variety of such materials are possible and hence a more continuous progression of lattice parameter could be produced [7][8][9][10][11].Due to high stability in hostile environment, many of the new technologies incorporate provskite structure based ceramics in their manufacture activities for such applications.We are working on fabrication of ceramic encapsulated temperature sensor for petroleum extraction industry [12][13][14] and in the present work we have devel-  For the fabrication of ceramic components and sintering of Ca 2 AlNbO 6 ceramics, circular discs of 30 mm diameter and 3 mm thickness were produced by uniaxial pressing technique using the same above referred mould and a hydraulic press at a pressure load of 12 ton/cm 2 .For better compression, each fraction of pressure was applied for 5 minutes to stabilize the pressure load distribution in the compact and homogenize the necessary pressure load.The compressed ceramic discs were subjected to normal solid state sintering process in a temperature range of 1250˚C -1350˚C for 24 hours in ambient atmosphere, using the same above referred high temperature muffle furnace and finally furnace cooled to room temperature.

Experimental Details
Microstructural analysis of the sintered Ca 2 AlNbO 6 ceramics was carried out by scanning electron microscopy (model JEOL JSM-5900), using secondary elec-trons.To observe the microstructure, the samples were placed in a metal coating device to receive a thin layer of gold, since they are not electrically conducting, necessary for secondary electron emission to get SEM images.Mechanical properties of the sintered ceramics were studied through Vicker's micro-hardness testing.For the indentation in Vicker's micro-hardness tester, the samples were polished with # 220, # 400, # 600, # 1200, # 1500 grade sand papers, followed by mechanical polishing using diamond paste with 1 micron particle size.For this testing a Vicker's hardness indenter model HVS-5 N˚ 0021 was used.The Vickers microhardness (MHV) is given by Equation ( 1 where, P is the load and d is the average diagonal of the square indentation produced by the pyramidal indentor in the sample.
For the study of stability of Ca 2 AlNbO 6 ceramics in petroleum extraction environment, sintered ceramics were submerged in crude petroleum for 60 days.Crude petroleum for this study, extracted from the earthen and offshore petroleum wells of the North-east region of Brazil, was provided by PETROBRAS, Brazil.Ca 2 AlNbO 6 ceramics were periodically taken out from the petroleum reservoir every 15 days and subjected to X-ray diffractometry, optical microscopy and mechanical testing to observe if there are any changes in their structural and mechanical characteristics due to crude petroleum environment.

Results and Discussion
The XRD pattern of a typical Ca 2 AlNbO 6 ceramics, produced in this work is shown in Figure 1.It consists of strong peaks characteristics of primitive cubic perovskite structure plus few weak reflection lines arising from the superlattice reflections.No evidence for a distortion from the cubic symmetry is observed in the XRD spectrum.The basic perovskite composition is ABO 3 , where A is a large ion suitable to the 12-coordinated cube-octahedral sites and B is a smaller ion suitable to the 6-coordinated octahedral site.Complex perovskite with mixed species on a site (particularly the B site) may be represented by multiples of this formula unit and a larger unit cell, e.g.A 2 BB'O 6 , A 3 B2B'O 9 etc.Thus, in Ca 2 AlNbO 6 composition, Ca 2+ , with largest ionic radius (1.05 Å) occupies position A, Al 3+ (ionic radius 0.55 Å) and Nb 5+ (ionic radius 0.70 Å) cations occupy B and B' positions on the B site due to their smaller ionic radii compared to that of Ca 2+ cation.Due to the ordering of B and B' on octahedral site of the ABO 3 unit cell there is a doubling in the lattice parameter of the basic cubic perovskite unit cell.Thus, the whole XRD pattern of Ca 2 AlNbO 6 can be indexed in an A 2 BB'O 6 cubic cell with the cell edge a = 2a p where a p is the cell lattice of the cubic perovskite.The XRD spectrum of Ca 2 AlNbO 6 is similar to A 2 BB'O 6 type complex cubic perovskite oxides e.g.Ba 2 YNbO , Ba 2 Er-SbO 6 , Ba 2 DyNbO 6 etc. reported in the JCPDS files, as judged by the similarity in d-spacings and intensity ratios.Experimental XRD data of Ca 2 AlNbO 6 ceramics is presented in Table 1 of the superstructure reflection lines (111) and (333) in the XRD spectrum of Ca 2 AlNbO 6 is the signature of an ordered complex cubic perovskite structure.In a substitutional solid solution BB', there is a random arrangement of B and B' on equivalent lattice positions in the crystal structure.Upon suitable heat treatment, the random solid solution rearranges into a structure in which B and B' occupy the same set of positions but in a regular way, such a structure is described as superstructure.In the superstructure, the positions occupied by B and B' are no longer equivalent and this feature is exhibited in the XRD spectrum of the material by the presence of superstructure reflection lines [16,17].
For double cubic perovskite of the formula A 2 BB'O 6 the intensity, in particular of the (111) and/or (311)  3) and ( 4) [18]: where, A , B , B and o R are ionic radius of A, B, B' cations and oxygen, respectively.Using these equations theoretical value of unit cell parameter of Ca 2 AlNbO 6 is a cal = 7.5148Å.Experimental value of unit cell parameter of Ca 2 AlNbO 6 (a exp = 7.6599 Å) is 1.93% higher than its theoretical value (a cal = 7.5148 Å), which can be justified because Shannon and Prewit model21 is based on hard sphere approximation.

R R R '
As stated earlier, the objective of this work is to produce Ca 2 AlNbO 6 ceramics with good mechanical strength in order to guarantee the required qualities that a final ceramic product must have for structural applications.Production and functional ability of polycrystalline ceramic products are highly dependent on their microstructural features, which in turn are highly influenced by sintering kinetics.Microstructural features define the final product quality of the ceramic products and their mechanical strength.
Microstructural features of Ca 2 AlNbO 6 ceramics sintered at different temperatures (1250˚C -1350˚C) for 24 hours, was studied by scanning electron microscopy.crohardness tests.These tests were performed on 10 polished discs of Ca 2 AlNbO 6 ceramics, sintered at each temperature (1250˚C -1350˚C), with 10 indentations on each discs to obtain the arithmetical mean value.Results of these tests are presented in Table 2. Ceramics sintered at 1350˚C presented much higher MHV values than ceramics sintered at lower temperatures, which is closely related to better microstructure of these ceramics ob-served in SEM studies.
For the study of stability of these ceramics in petroleum environment, we used Ca 2 AlNbO 6 discs sintered at 1350˚C as these discs presented better microstructural features and mechanical hardness.These discs were firstly polished with mirror like polished surface and subjected to optical microscopy.After observation in optical microscopy these discs were partitioned in two equal parts, using diamond disc cutter, to be submersed each one part in the crude petroleum extracted from earthen and offshore petroleum wells, respectively.This was carried out purposely to ensure that ceramics submersed in crude petroleum extracted from earthen and offshore petroleum wells have the same microstructure and mechanical hardness.Ceramics were submerged in crude petroleum for 60 days.Ceramics were taken out from the petroleum reservoir periodically, every 15 days and tested to observe if there are any changes in their structural, microstructural and mechanical characteristics due to crude petroleum environment.
Typical results of X-ray diffractometry carried out on Ca 2 AlNbO 6 ceramics after 60 days of submersion in earthen and offshore crude petroleum are shown in    3.As we can see from these results Ca 2 AlNbO 6 ceramics did not suffer practically any change in their mechanical hardness due to due to crude petroleum environment.
Microstructural analysis of Ca 2 AlNbO 6 ceramics after submersion in crude petroleum was carried out using optical microscopy because after submersion in crude petroleum it was extremely difficult to use scanning electron microscopy because of vacuum necessities.Figure 4 presents the optical micrographs of Ca 2 AlNbO 6 ceramics before and after submersion in crude petroleum for 45 and 60 days respectively.As seen from Figure 4, microstructural features of Ca 2 AlNbO 6 ceramics remain identical before and after submersion in crude petroleum without any degradation in microstructural features due to crude petroleum environment.
From these promising results we conclude that Ca 2 Al-NbO 6 ceramics are stable in crude petroleum environment and thus could be potential candidate ceramic encapsulation in the fabrication of temperature sensors for temperature monitoring in petroleum wells.

Conclusion
In the present work we have produced a niobium based complex cubic perovskite oxide Ca 2 AlNbO 6 ceramics and studied their stability in crude petroleum environment for the manufacture of inert ceramic embedding for temperature sensors used in petroleum extraction.Ca 2 Al-NbO 6 ceramic powder was prepared through thermomechanical solid-state processing route.Structural characteristics and phase identification of calcined material was investigated by powder X-ray diffarctometry, which presented a single phase complex cubic perovskite structure with lattice parameter a = 7.6599 Å. Microstructure of the Ca 2 AlNbO 6 ceramics, sintered at 1350˚C presented a high homogenous morphology and particle size distribution.Mechanical behavior of the sintered ceramics was studied by Vickers micro-hardness testing, which gave a reasonable value of MHV = 287.72,for ceramics sintered at 1350˚C, which is reasonable for encapsulation application of these ceramics.Results of X-ray diffractometry, microstructural and mechanical tests showed that Ca 2 Al-NbO 6 ceramics submerged in crude petroleum did not suffer any change at any stage of submersion.From these promising results we conclude that Ca 2 AlNbO 6 ceramics are stable in the aggressive crude petroleum environment

Fig- ure 3
along with the XRD spectra of Ca 2 AlNbO 6 ceramics before submersion in crude petroleum.As seen from Figure3both the XRD spectrum of Ca 2 AlNbO 6 ceramics submersed in earthen and offshore petroleum are

Figure 3 .
Figure 3. X-ray diffraction patterns of Ca 2 AlNbO 6 ceramics: (a) Before submersion in crude petroleum; (b) After 60 days submersion in earthen crude petroleum and (c) After 60 days submersion in off shore crude petroleum.

Figure 4 .
Figure 4. Optical micrograph (200×) of Ca 2 AlNbO 6 ceramics before and after submersion in crude petroleum: (a) before submersion in crude petroleum; (b) and (c) after 45 and 60 days submersion, respectively, in earthen crude petroleum and ((d) and (e)) after 45 and 60 days submersion, espectively, in offshore crude petroleum.r Production of Ca 2 AlNbO 6 Ceramics and Study of Their Stability in Crude Petroleum for the Conservation of Metallic Sensing Elements Used in Petroleum Extraction 409 oped and produced niobium based complex cubic perovskite oxide Ca 2 AlNbO 6 ceramics and studied their stability in crude petroleum environment for the fabrication of inert ceramic embedding for temperature sensors used in petroleum extraction.