Abstract
ZrO2-3 mol % Y2O3-coated AISI 310 stainless steel was nitrided using plasma produced by dc pulsed discharge in a mixture of N2 and H2 at an equilibrium temperature of 450ºC. Profile chemical analyses with GDOS (glow discharge optical spectroscopy) and XRD showed the formation of Nitrogen/Y-ZrO2 solid solution. Nitrogen atoms enter in the zirconia substituting to the oxygen atoms in the network. Although, the nitrogen content measured in zirconia coating is greater than the allowed maximum nitrogen content in doped-zirconia solid solution, the formation of oxynitrides could not be detected. The phase structure was investigated by X-ray diffractometry The mechanical properties were studied by means ultramicrohardness indentation tests. The nitruration improves the mechanical responses of the ZrO2-3 mol% Y2O3 -coated AISI 310 stainless steel.
Ion nitriding; Zirconia coatings; Nitrurated coatings
SURFACES, INTERFACES, AND THIN FILMS
Influence of ion nitriding process on the properties of zirconia coating deposited on stainless steel
B. J. GómezI; R. CarusoI, II; L. NachezI; A. Díaz-ParralejoIII; J. FeugeasI; O. de SanctisI, II
IIFIR,(CONICET-UNR) Bv. 27 de Febrero 210 bis S2000EZP Rosario, Argentina
IILab. Mat. Ceram. UNR Pellegrini 250, 2000 Rosario, Argentina
IIIUniversidad de Extremadura, 06071 Badajoz, España
ABSTRACT
ZrO2-3 mol % Y2O3-coated AISI 310 stainless steel was nitrided using plasma produced by dc pulsed discharge in a mixture of N2 and H2 at an equilibrium temperature of 450ºC. Profile chemical analyses with GDOS (glow discharge optical spectroscopy) and XRD showed the formation of Nitrogen/Y-ZrO2 solid solution. Nitrogen atoms enter in the zirconia substituting to the oxygen atoms in the network. Although, the nitrogen content measured in zirconia coating is greater than the allowed maximum nitrogen content in doped-zirconia solid solution, the formation of oxynitrides could not be detected. The phase structure was investigated by X-ray diffractometry The mechanical properties were studied by means ultramicrohardness indentation tests. The nitruration improves the mechanical responses of the ZrO2-3 mol% Y2O3 -coated AISI 310 stainless steel.
Keywords: Ion nitriding; Zirconia coatings; Nitrurated coatings
I. INTRODUCTION
Nitrided metals have excellent mechanical properties such as high hardness and wearing resistance. On the other hand, yttria-stabilized zirconias (YSZ), in addition to having good mechanical properties, such as high hardness and fracture toughness, exhibit outstanding thermal stability and corrosion-resistant properties [1]. Consequently, yttria-stabilized zirconia is widely used as protection coating for metallic surfaces where thermal and corrosion resistance are required [2].
Nitrogen-containing zirconia solid solution and zirconium oxynitrides (e.g.,g-Zr2ON2) have attracted attention due to their improved mechanical and thermal properties as compared with those obtained for oxide based systems [3, 4]. Several processes can be used to nitriding zirconia such as solid-state reactions [5] or reaction in vapor phase [6]. Most of them are generally based on treatments to high temperatures. The ion-nitriding process has been widely used to nitride metallic surfaces, normal steels and stainless steels at relatively low temperature [7, 8]. The aim of the present work is to use the ion-nitriding process in nitriding yttria-stabilized zirconia films deposited on AISI 310 stainless steels. The composition, crystalline structural and mechanical properties of the prepared samples will be analyzed.
II. EXPERIMENTAL DETAILS
A. Yttria-doped zirconia coating preparation
The starting solution was prepared by stirring zirconium n-propoxide (ZNP) (70 wt% in 2-propanol Alfa 22989), 1- propanol and HNO3 as catalyst agents in an anhydrous N atmosphere to avoid hydroxide precipitation. After 6 h, distilled water was carefully added, followed by stirring during 24 h until a quite transparent solution was obtained. The ZNP/H2O/HNO3 molar ratios achieved the 1/7/1 values and the ZrO2 concentration in the solution was 77 g/l. The final sol-gel solution was obtained by adding in the Zr solution Yttrium acetate (99.9%) dissolved in PrOH and HNO3. This step was performed under stirring in normal atmosphere. The resulting ZNP/PrOH/H2O/HNO3 molar ratio was 1/15/5/1, and the nominal concentration of yttria in oxide was 2.5 mol%. The AISI 310 stainless steel substrate (supplied by Goodfellow Ltd.) were polished (1 µm diamond paste) and cleaned in ethanol. In order to enhance the adhesion of the zirconia films, the metallic substrate was oxidized by heat treatment at 300 ºC in air for 1 h before depositing the films by the dip-coating method [9]. The dipping was made with a withdrawal rate of 14 cm/min. A 10 layer coating of about 2 µm was produced by a multilayer deposition process [10]. After each deposition, the film was dried and after heated at 800 ºC for 2 h in normal atmosphere.
B. Plasma reactor and nitriding conditions
The plasma is generated as quiescent discharge (glow discharge) inside the reactor chamber, between the cathode (samples holder) and the grounded anode (chamber walls) [11]. The gas composition was 70 % N2 mixed with 30 % H2 maintained inside the chamber at a constant pressure of 533.3 Pa and at 450 ºC (equilibrium temperature) for 5 h. In this work, the applied voltage, frequency and the active to passive ratio was 500 V, 100 Hz and 80 % to 20 %, respectively.
C. Coating characterization
The XRD pattern was obtained using a Philips PW-1800 powder diffractometer with CuKa radiation (l = 1.54183 Å). The diffraction data were collected over a 2q range of 25-90º with a step width 0.02º of and a counting time of 5 s/step. Depth profiling element analyses were obtained using a Leco glow discharge-optical emission spectrometer (Grimm-type lamp, 4-mm anode diameter) applying a electric discharge onto the sample surface at controlled voltage, current, and Ar atmosphere [10].
Sputter rates were roughly calibrated using ZrO2 multilayer coatings prepared by the authors with thickness and porosity pre-determined [10, 12]. Coating thickness is estimated by assuming that the metallic/ ceramic interface is located where the Iron (Fe) content is 50the bulk substrate value.
Ultramicrohardness tests were performed to study the mechanical response of the samples. The values of ultramicrohardness (H) and the Young's modulus (E) were obtained, from the indentation load-unload curves [13], [14]. The tests were performed at loads of 20 mN by using a Berkovich indenter (three-sided pyramid).
In order to overcome measurement errors due to imperfections in the indenter tip, Indentation Size Effect corrections [10], H and E values were measured by conventional tests on AISI 310 and reference materials (bulk Mg-partially stabilized zirconia, and sapphire) and compared with the values obtained by ultramicrohardness tests.
The H was measured with Vickers indenter (Shimadzu Micro Hardness Tester Type M) using a load of 200 g. Hertzian contact tests [15] were used to determine the elastic modulus of bulk materials (AISI 310 substrate, bulk Mg-PSZ and sapphire), using a mechanical testing machine with load-depth data acquisition software (Instron 5565, Instron Corp., Canton, MA).
III. RESULTS AND DISCUSSION
A. Depth profiling quantitative analysis
Fig. 1 shows the elemental depth profile obtained in the coating deposited on the AISI 310 (Sample C). The [Zr]/[O] ratio maintains almost constant equal to 0.5 throughout the coating. [Zr] steeply decreases in the zone where [Fe] increases, which is located around a depth of 2 µm, and it forms an intermediate region between zirconia coating and metallic substrate of about 300 nm.
The depth profiling analysis of nitrided coating (Sample NC) shows (Fig. 2) that the [N] is very high near the surface ( » 0.9), and steeply, it decreases to a value of » 0.4 at a depth with depth of 0.250 µm, deeper the [N] decreasing lightly until near the interface. On the interface, [N] falls fast until being almost negligible in the metallic substrate. Tacking into account the result in the ion nitrided steel substrate where the N diffuse far away from the surface (estimated roughly in 100 µm), the almost negligible [N] in the metallic substrate for nitriding zirconia-AISI 310 would act as a barrier that inhibits the N diffusion. Also from a chemical composition point of view, the [N] (an average concentration of 0.3) in the zirconia coating (Fig. 2) is an unexpected result, because it is grater than the maximun [N] in solid solution as well as than the [N] as oxynitrides.
B. Structural and microstructural characterization
Fig. 3 shows the XRD pattern of sample C and NC . The XRD spectrum of the NC exhibits a change only a high angle peaks shifting with respect to the spectrum of the C, which indicates a decrease in the lattice parameter. The smaller lattice parameter would indicate than N atom enter in the zirconia substituting the O atoms in the network. This result has been previously reported in bulk samples for Nitrogen-containing 8Y/ZrO2 fully cubic stabilized zirconia [16]. In order to maintain network neutrality, the introduction of the N into zirconia results in O vacancies in the anion sub-lattice as required N3- substitution for O2- anions. Therefore, the O vacancies in the 3Y/ZrO2 films are in fact a combination of the vacancies introduced by both Y3+ (Y3+ substituted for Zr4+ in the cation sub- lattice) and N3- (N3- substituted for O2- in the anion sub-lattice) giving a formula:
Taking into account the results obtained by Cheng and Thompson [16] that the [N] cubic Zirconia becomes unstable when the overall O vacancies are beyond » 6 % ([VO··]/[Zr] = 0.12), resulting xmax = 0.18 and consequently [N]max/[Zr] » 0.2. The [N]/[Zr] ratio in the ion nitrided 3Y/ZrO2 films is five times that maximum [N]max/[Zr]. Therefore, it was expected the formation of Zirconium nitride and/or Zirconium oxynitrides. However, the Zirconium nitride peaks are not observed and could not be asserted undoubtedly the presence of the room temperature stable Zirconium oxynitride (g-Zr2ON2) because their peaks are severely overlapped with those of the zirconia cubic phase. Taking into account the low temperature of ion nitriding process, it is possible to hypothesize the presence of N2 trapped inside either the central octahedral interstices of zirconia structure or in the residual pores of the coating.
C. Mechanical properties
Figure 4 shows the experimental Berkovich load-penetration depth curves corresponding to the bared AISI 310 substrate (S), sample C and bulk Mg-PSZ sample (Z). This latter sample has been incorporated as reference material. In order to analyze the intrinsic mechanical response of coating the penetration depth of the Berkovich indenter was less than 1/7 of the coating thickness. The curve of sample C shows typical behaviour of a ceramic material characterized by a major elastic recovery during unloading (about 60 %) and a penetration depth at 20 mN load that is about a half of the one corresponding to the metallic surface. Fig. 5 shows the experimental load-penetration depth curves corresponding to the sample NC. As references, the figure also includes the indentation curve of sample C and to the bulk sapphire sample (SA).
Using the method described in a previous work [10], we have obtained the H* and E* of the samples. The results are shown in Table I with an error estimated of about 5 %.
The ion nitriding process had increased the mechanical response of the coating, as can be seen from the higher H* and E* values of the NC respect to the observed for C. In order to be sure that the values obtained by Berkovich ultramicrohardness tests are not distorted by errors inherent to measurement method [10], conventional tests were performed on the bulk materials (Table I). The values obtained by both method are very similar as well as to the data found in the literature for those materials [17, 18].
IV. CONCLUSIONS AND IMPLICATIONS
ZrO2-3 mol % Y2O3 on AISI 310 stainless steel has been nitrided using an ion-nitriding process at 450º, in N2/H2 plasma.We have found that the ion-nitriding process allows the incorporation of higher [N] into the zirconia coating at lower temperatures than with the corresponding one to conventional processes. Although the highest [N] observed in the most superficial layer of the zirconia coating, the N diffuses along the whole of the layer of the zirconia until the zirconia-steel interface. However, the N locates mainly in the zirconia film and almost vanishes in the stainless steel substrate. This behaviour can be explained looking the zirconia coating as a trap for the N, screening the diffused N toward the stainless steel substrate. O substitution by N entering the zirconia layer is suggested as the trapping mechanism. The introduction of N into ZrO2-3 mol% Y2O3 creates additional O vacancies in the anion sublattice as required by charge neutrality for N3- replacing O2- in the structure. On the other hand, as the formation of oxynitrides compounds have not been undoubtedly observed, the excess of the N can be attributed to the presence of N2 inside the zirconia coatings. Finally, we have shown that the ion nitriding process improves the mechanical responses of the ZrO2-3 mol % Y2O3-coated AISI 310 stainless steel.
Acknowledgments
A grateful acknowledgment to Conicet (Argentina) and the Agencia Nacional de Promoción Científica y Tecnológica, Argentina,
Received on 8 December, 2005
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Publication Dates
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Publication in this collection
29 Nov 2006 -
Date of issue
Sept 2006
History
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Received
08 Dec 2005