Abstract

Nanostructured and conventional TiAlN and AlCrN coatings were deposited on ASTM-SA210 Grade A-1 boiler steel. The present work has been focused to characterize the conventional thick (by plasma spraying and gas nitrided) and nanostructured thin (by physical vapor deposition process) TiAlN and AlCrN coatings developed on ASTM-SA210 Grade A-1 boiler steel. The surface morphology of the coated samples was studied using FE-SEM with EDAX attachment, XRD analysis, AFM analysis, and the X-ray mapping analysis. The presence of metal nitride phases as identified by XRD analysis indicates that the desired coatings were successfully developed. The bond strength, surface roughness, and microhardness of the gas nitrided plasma sprayed conventional coatings were measured. A good adhesion of the conventional thick TiAlN and AlCrN coatings was evident from bond test results.

1. Introduction

The boiler components are subjected to various types of degradation phenomenon such as high-temperature corrosion, erosion corrosion, overheating, solid particle abrasion and wear. High-temperature oxidation and erosion caused by the impact of fly ashes and unburnt carbon particles are the main problems to solve in these applications. Therefore, the development of wear and high-temperature oxidation protection systems in industrial boilers is a very important topic from both engineering and an economic perspective [1, 2]. Present materials being capable of resisting erosive and corrosive environments are highly alloyed and thus expensive. In search for cost-effective solutions for erosion-corrosion problems, the effective method of erosion-corrosion prevention is to coat the alloy with a protective layer, which has been used in the current investigation.

The high-temperature protection system must meet several criteria: that is, it should provide adequate environmental resistance, be chemically and mechanically compatible with the substrate, and be practically applicable, reliable, and economically attractive [3]. The primary aim of the coating/surface treatment is the ability to produce a stable, slow-growing surface oxide providing a barrier between the coated alloy and the environment [4]. Recent studies show that 80% of the total cost for the protection of metals is related to coating application [5, 6].

According to DeMasi-Marcin and Gupta [7], physical vapor deposition and plasma spray (a thermal spray process) have been reported to be two major coating processing technologies which are used worldwide. The PVD processes have been successful in improving mechanical properties such as wear, friction, and hardness [8]. Their use as corrosion-resistant coatings is also becoming widespread. Among the thermal spray coating processes, plasma spraying is reported to be versatile technology that has been successful as a reliable cost-effective solution for many industrial problems [9, 10]. Since the commercialization of physical vapor deposited (PVD) TiN coatings in early 1980s, transition metal nitrides based hard coatings have been successfully used for the materials protection particularly to improve cutting tools lifetime [11].

In recent years, corrosion performance of nanostructured materials/coatings is a hot topic in corrosion field [12, 13]. Nanostructured materials as a new class of engineering materials indeed behave differently from their microscopic counterparts because their characteristic sizes are smaller than the characteristic length scales of physical phenomenon occurring in bulk materials [14]. As reported by Chawla et al. [15, 16], in the past decade, attractive properties associated with a nanostructure have been documented for bulk materials, where most of the research in the field of nanomaterials has been focused. Little work has been published on high-temperature corrosion behavior of nanostructured and conventional hard metal nitride coatings to the best of knowledge of the author. Therefore, these coatings were developed on the ASTM-SA210 Grade A-1 boiler steel, and their behavior was studied when exposed to high-temperature oxidation in air, molten salt environment, industrial environment, high temperature solid particle erosion, and simulated marine environment. The present work has been focused to characterize the conventional thick (by plasma spraying and gas nitrided) and nanostructured thin (by physical vapor deposition process) TiAlN and AlCrN coatings developed on ASTM-SA210 Grade A-1 boiler steel.

2. Experimental Details

2.1. Selection of Substrate and Sample Preparation

The boiler steel material “ASTM-SA210 Grade A-1” has been selected for the present study as the substrate material. Selection of candidate material for the study has been made after consultation with Guru Nanak Dev Thermal Plant, Bathinda (India). Grade A-1 has a wide range of applications in boilers, especially in the construction of their water walls. The actual chemical composition of the selected alloy has been determined with the help of Optical Emission Spectrometer (Thrmo Jarrel Ash, TJA181/81, USA), which is reported in Table 1 along with nominal chemical composition.

Specimens with dimensions of approximately 20 mm × 15 mm × 5 mm were cut from the alloy sheets. The specimens were polished using emery papers of 220, 400, 600 grit sizes and subsequently on 1/0, 2/0, 3/0, and 4/0 grades. Then the samples were mirror polished using cloth polishing wheel machine with 1 μm lavigated alumina powder suspension for deposition of nanostructured coatings and grit blasted with alumina powders (Grit 45) prior to the deposition of the conventional coatings by plasma spraying (a thermal spray process), for developing better adhesion between the substrates and the coatings. The specimens were prepared manually, and whole care was taken to avoid any structural changes in the specimens.

2.2. Development of Nanostructured Thin Coatings

The nanostructured thin TiAlN and AlCrN coatings, with a thickness around 4 μm, were deposited on the substrates at Oerlikon Balzers Coatings India Limited, Gurgaon, India. A front-loading Balzer’s rapid coating system (RCS) machine (made in Oerlikon Balzers, Swiss) was used for the deposition of the coatings. The machine is equipped with 6 cathodic arc sources. In case of nanostructured thin TiAlN coatings, two of the six sources were used to deposit a thin, 0.3 μm thick TiN sub-layer to improve adhesion of coating. The remaining four sources were employed to deposit the main layer of the coatings, which was obtained using customized sintered targets. Whereas in case of nanostructured thin AlCrN coating, all the six targets sources were employed to deposit the main layer of the coatings. The Oerlikon Balzers Coatings India Limited, Gurgaon, India has optimized the coating parameters for all the substrates. The compositions of the targets used, coating thickness and the summary of the process parameters, are presented in Table 2. For all coatings, argon (Ar) and pure nitrogen atmosphere were used during deposition. Prior to deposition all the substrates were cleaned in two steps: firstly with Ultrasonic Pre-Cleaner (made in Imeco, Pune, India) and secondly with Ultrasonic Cleaning Machine with 9 Tanks including hot air dryer (make Oerlikon Balzers Ltd. India) for 1.5 Hrs.

2.3. Development of Conventional Thick Coatings

Two types of coating powders, namely, Ti-50Al (50 Ti-50 Al Wt%) and Al-30Cr (70 Al-30 Cr Wt%) were chosen for plasma spray deposition on the substrate. These powders were prepared in laboratory ball mill for 8 hrs to form a uniform mixture from three types of commercially available alloy powders, namely, titanium powder with minimum assay 98.0% (Art. 6322) supplied by Loba Chemie, Mumbai, India, aluminum powder with minimum assay 90.0% and size 200 mesh (Art. 37064) and chromium powder with minimum assay 99.0% and size 60 mesh (Art. 36054) supplied by S.D. Fine Chemical Limited, Mumbai, India. The coating work were carried out a commercial firm, namely, Anod Plasma Limited, Kanpur, India. They used 40 kW Miller Thermal (USA) plasma spray apparatus to apply the coatings. Argon was used as powder carrying and shielding gas. Standard spray parameters were designed by the previous firm for depositing the coatings in the present work. All the process parameters were kept constant throughout the coating process while spraying distance was maintained in a narrow range of 90–110 mm. The process parameters for the shrouded plasma spray process employed for applying the coatings are summarized in Table 3.

Gas nitriding is a case hardening process whereby nitrogen is introduced into the surface of an alloy by holding it at a suitable temperature in contact with a nitrogenous gas, that is, nitrogen or ammonia. After reviewing the literature critically, it was decided to do the gas nitriding of the plasma sprayed conventional thick Ti-Al and Al-Cr coatings in the lab. The apparatus used for the gas nitriding process is shown in Figure 1, which consists of a long steel tube placed in a silicon tube furnace. In the front view (Figure 1), the steel tube is connected to the nitrogen cylinder for nitrogen supply, and in the rear view, the outlet of the nitrogen gas is through water for slow and constant discharge rate. The gas nitriding parameters were optimized after conducting several trials on plasma sprayed coated specimens. The process parameters employed for the gas nitriding are as summarized in Table 4.

2.4. Characterization of the Coatings

Field emission scanning electron microscope (FESEM, FEI, Quanta 200F Company) with EDAX Genesis software attachment (made in Czech Republic) is used to characterize the surface morphology of the coatings. SEM micrographs along with EDS spectrum were taken with an electron beam energy of 20 keV. The surface morphology (2D and 3D) of the thin films was also characterized by AFM (Model: NTEGRA, NT-MDT, Ireland) to calculate the surface roughness and particle size.

The coated specimens were subjected to XRD analysis using Bruker AXS D-8 advance diffractometer (Germany) with Cu K radiation. The scan rate used was 2°/min and the scan range was from 20° to 120°. The grain size of the thin films was estimated from Scherrer formula, as given in (1). In this expression, the grain size is along the surface normal direction, which is also the direction of the XRD diffraction vector: where is the corrected full-width at half maximum (FWHM) of a Bragg peak, is the X-ray wavelength, and is the Bragg angle. is obtained from the equation , where is the FWHM of a measured Bragg peak, is the lattice broadening from the residual strain measured by XRD using the method, and is the instrumental line broadening. A Zeiss Axiovert 200 MAT inverted optical microscope, fitted with image software Zeiss Axiovision Release 4.1, was used for optical microscopy. The porosity measurements were made with image analyser, having software of Dewinter Materials Plus 1.01 based on ASTM B276. A PMP3 inverted metallurgical microscope was used to obtain the images.

The as-coated specimens were cut with a diamond cutter (Buehler’s Precision Diamond Saw, Model ISOMET 1000, made in USA) across its cross-section and subsequently hot mounted in Buehler’s transoptic powder (20-3400-080). Subsequently, the mounted specimens were polished manually using emery papers of 220, 400, and 600 grit sizes and subsequently on 1/0, 2/0, 3/0, and 4/0 grades. Finally, the specimens were mirror polished on a cloth polishing wheel machine with 0.05 μm alumina powder suspension. The specimens were washed thoroughly with flowing water and dried in hot air to remove any moisture.

The thickness of the coatings was monitored during the coating processes. In case of plasma sprayed conventional thick coatings, the thickness was monitored with a Minitest-2000 thin film thickness gauge (made in Germany, precision ±1 μm). Efforts were made to obtain the coatings with uniform thickness. The thickness of some of the as-coated specimens (nanostructured as well as conventional coatings) was further verified by cutting along the cross-section and mounted (as explained previously). A Field emission scanning electron microscope (FE-SEM)(FEI Quanta 200F, made in Czech Republic) was used to obtain the back scattered electron (BSE) images.

The bond strength of the gas nitrided plasma sprayed coatings was tested using the ASTM standard C633-01. This test method covers the determination of the degree of adhesion (bonding strength) of a coating to a substrate or the cohesion strength of the coating in a tension normal to the surface. The test consists of coating one face of a substrate fixture, bonding this coating to the face of a loading fixture, and subjecting this assembly of coating and fixtures to a tensile load normal to the plane of the coating. A data acquisition system has continuously recorded the tensile load exerted by the machine. The surface roughness () values of the gas nitrided plasma sprayed as coated specimens were measured using Surface Roughness Tester (Mitutoyo SJ-201, Japan). Each reported value of surface roughness () is the mean of five observations taken at different locations. The centre line average (CLA) method was used to obtain the values.

X-ray mapping analysis of the samples was done on field emission scanning electron microscope (FEI, Quanta 200F Company) for image acquisition entailed a backscattered electron image (BSEI) and secondary electron image (SEI) mode. An accelerating voltage of 20–25 kV, a working distance of 9–10 mm, and an image size of 1024*884 pixels were used for getting quality images. Energy Dispersive X-ray Analysis (EDAX) and X-ray mapping were employed while imaging on FE-SEM was carried out to obtain elemental composition at different areas of the coating and surface morphology of the coatings, respectively. The specimen were silver pasted between samples and the stub in order to have conductivity, thereafter, gold-coated to facilitate elemental X-ray mapping analysis of the different elements present across the coating. The selected area has three regions, that is, substrate, coating, and some epoxy region. X-ray mappings were obtained for all the elements of the substrate and the coatings, but only those mappings are reported which indicates the presence of some element.

For obtaining microhardness of the gas nitrided plasma sprayed conventional coatings, the specimens were cut, mounted, and polished (as explained polished). The microhardness of the as sprayed coatings was measured by using Miniload 2 Microhardness Tester (Leitz, Germany) fitted with a Vickers pyramidal diamond indenter. A 15 g (147.1 mN) load was applied to the indenter for penetration of as sprayed coatings. Hardness value was calculated from the relation where “” is the load in grams and “” is the diameter of the indenter in micrometer. Each reported value of the microhardness is the average value of five measurements.

3. Observations and Results

3.1. Visual Observations

The nanostructured thin (by Physical Vapor Deposition process) and conventional thick (by plasma spraying and gas nitriding) TiAlN and AlCrN coatings have been formulated successfully on ASTM-SA210 Grade A-1 boiler steel. The macrographs of as-coated Grade A-1 boiler steel are shown in Figure 2. It can be observed from the macrographs that the nanostructured thin TiAlN coating is violet grey in color and nanostructured thin AlCrN coating is light grey in color. Visual observations indicate that the surface of nanostructured coatings is smooth, whereas the surface of conventional thick coatings is rough. The color of the thick coatings appeared as grey with some bluish shining. Also, optical micrographs of the nanostructured and conventional coatings are shown in Figure 3. The nanostructured coatings (Figures 3(a) and 3(b)) have uniform microstructure. It is evident from the microstructure that the coatings contain some pores and inclusions. In case of conventional thick coatings (Figures 3(c) and 3(d)), the massive microstructure can be observed with irregularly shaped grains.

3.2. Surface Analysis
3.2.1. X-Ray Diffraction Analysis (XRD)

XRD diffractograms for nanostructured and conventional TiAlN and AlCrN coated ASTM-SA210 Grade A-1 boiler steel are depicted in Figure 4 on reduced scale. As indicated by the diffractograms in Figure 4; TiN and AlN are the main phases present in the nanostructured thin TiAlN coating. Further, in case of nanostructured AlCrN coating, the prominent phases are CrN and AlN. The grain size of the nanostructured thin coatings was estimated from Scherrer formula; which is reported in Table 5. The calculated grain size for nanostructured thin TiAlN and AlCrN coatings is 16 and 26 nm, respectively. Further, the main phases identified for the conventional thick TiAlN coating are Al2O3, TiN, Ti3Al, AlN and small peaks of TiO2 and Fe2O3. The phases identified in case of conventional thick AlCrN coating are CrN, AlN, and Al2O3 with minor peaks of Cr2O3.

3.2.2. Porosity Analysis

The porosity analysis is of prime importance in high temperature corrosion studies. The dense coatings are supposed to provide very good corrosion resistance as compared to porous coatings. The porosity measurements were made by PMP3 inverted metallurgical microscope with stereographic imaging. The porosity of nanostructured thin TiAlN and AlCrN coatings was found below 0.5% (Table 5). In case of conventional thick coatings; the porosity of as-sprayed Ti-Al (2.30–4.25%) and Al-Cr (2.00–4.30%) coatings was also evaluated, which is reported in Table 6. A considerable decrease in the porosity had been observed after gas nitriding, and it was found to be less than 0.6% (Table 6).

3.2.3. AFM Analysis of the As-Deposited Nanostructured Thin Coatings

The surface topography of the nanostructured thin TiAlN and AlCrN coatings was studied using Atomic Force Microscope (AFM: NT-MDT: NTEGRA Model) in semi-contact mode. Figure 5 shows the AFM surface morphology (2D and 3D) of the nanostructured thin TiAlN and AlCrN coatings deposited on ASTM-SA210 Grade A-1 boiler steel. The difference in the morphology between the two coatings can be inferred by comparing the 2D images in Figures 5(a) and 5(c); however, a clearer comparison of the coatings could be afforded by viewing 3D images in Figures 5(b) and 5(d). As the axis scale indicates, the overall roughness of the nanostructured TiAlN coating (Figure 5(b)) is less than that of AlCrN coating (Figure 5(d)). The surface roughness and particle size in the coatings are analyzed by AFM analysis, reported in Table 5. The surface roughness in case of nanostructured TiAlN coating was observed to be 3.75 nm and 6.10 nm in case of nanostructured AlCrN coating (Table 5). The nanostructured thin TiAlN coating had shown lesser particle size (18 nm) as compared to nanostructured thin AlCrN coating (28 nm).

3.2.4. Surface Roughness () Values of the Conventional Thick Coatings

The coating surface was very rough in case of conventional thick TiAlN and AlCrN coatings due to the presence of melted/partially melted particles and the roughness were found to be in the range of 10.35–15.13 μm and 11.84–15.23 μm, respectively. The centre line average (CLA) method was used to obtain the values.

3.2.5. Evaluation of Microhardness and Bond Strength of the Conventional Thick Coatings

The hardness of the coatings has been measured along the cross-section of the conventional thick TiAlN and AlCrN coated Grade A-1 boiler steel. Figure 6 shows the microhardness profiles along the cross-section of the coatings as a function of distance from the coating-substrate interface. The critical hardness values of the substrate Grade A-1 boiler steel was found to be in the range 200–250 Hv. From the microhardness profiles (Figure 6) it is obvious that the conventional TiAlN coating has shown maximum microhardness of the order of 900–950 Hv. The conventional thick AlCrN coating has shown microhardness of the order of 600–700 Hv.

The bond strength of the conventional thick TiAlN and AlCrN coatings was measured on three specimens as per ASTM standard C633-01. The coatings failed at the substrate-coating interface while remaining attached to the adhesive (Figure 7). Average bond strength of 68.74 MPa and 54.69 MPa was observed in case of conventional TiAlN and AlCrN coatings, respectively (Table 6).

3.2.6. Surface Morphology of Coatings

FE-SEM micrographs along with EDS spectrum that reveal the surface morphology of the nanostructured and conventional TiAlN and AlCrN coated ASTM-SA210 Grade A-1 boiler steel are shown in Figure 8. Micrograph (Figure 8(a)) for nanostructured thin TiAlN coating at higher magnification (10000x) indicates grey matrix with some black and white contrast regions. Dense structure with lower porosity is observed in the coating microstructure, and also it is free from cracks. EDAX analysis at point 1 and point 2 in Figure 8 indicates the presence of Ti, Al, and N with negligible amount of Fe. The black colored areas revealed the higher amount of Ti and less concentration of Al as compared to the white contrast region. In case of nanostructured thin AlCrN coated Grade A-1 boiler steel, the FE-SEM micrograph indicates dense grey colored coating with tiny dark grey particles dispersed in the matrix. EDAX point analysis (points 3 and 4 in Figure 8) shows the coating is rich in Al, Cr, and N along with small amount of Fe and oxygen (Figure 8(b)).

The micrographs in case of conventional plasma sprayed gas nitride TiAlN and AlCrN coatings are shown in Figures 8(c) and 8(d). In general microscopic features indicate that the conventional coatings are homogeneous and massive, free from cracks. Presence of some oxide stringers as well as open pores has been noticed in general in the conventional coatings. The EDAX point analysis (point 5 and 6 in Figure 8) in case of conventional TiAlN coating indicates the higher concentration of Ti and Al in the coating along with some amount of N and oxygen. The presence of Al and Cr along with N and oxygen is revealed by EDAX analysis in case of conventional AlCrN coating (points 7 and 8 in Figure 8).

3.3. Cross-Sectional Analysis
3.3.1. Coating Thickness

The as-coated samples were cut across the cross-section using Buehler Isomet 1000 precision saw and mounted in transoptic mounting resin and subsequently mirror-polished to obtain scanning electron back-scattered micrographs and X-ray mapping of different elements for coated and uncoated ASTM-SA210 Grade A-1 boiler steel. The coating thickness values were measured from SEM back-scattered micrographs as shown in Figure 9 and average coating thickness is reported in Table 6. The measured average coating thickness values for nanostructured thin and conventional thick TiAlN and AlCrN coatings are 6.1, 4.2, 172, and 166 and 122 μm, respectively.

3.3.2. X-Ray Mapping

BSEI and X-ray mapping analysis for nanostructured and conventional TiAlN and AlCrN coated ASTM-SA210 Grade A-1 boiler steel is shown in Figure 9. The BSEI and X-ray mapping analysis of the nanostructured TiAlN coated Grade A-1 boiler steel are presented in Figure 9(a). The X-ray mapping indicates presence of Al and Ti along with small amount of N in the coating, and no diffusion of Fe from the substrate has been observed. In case of nanostructured thin AlCrN coated Grade A-1 boiler steel, the BSEI and X-ray mapping are shown in Figure 9(b). The X-ray mapping indicates the presence of Al and Cr along with some concentration of N in the coating, and no diffusion of Fe and other elements from the substrate has been observed.

In case of conventional thick TiAlN coated Grade A-1 boiler steel, Figure 9(c), Al- and Ti-rich coating along with negligible amount of N and O has been observed. The diffusion of Fe from the substrate has taken place as indicated by X-ray mapping analysis. Figure 9(d) depicts the BSEI and X-ray mapping in case of conventional AlCrN coated Grade A-1 boiler steel. The coating is rich in Al and Cr with negligible presence of N and O. The X-ray mapping analysis indicates the presence of thin horizontal bands of Al and O in the coating.

4. Discussion

The nanostructured thin TiAlN and AlCrN coatings on ASTM-SA210 Grade A-1 boiler steel were obtained using a front-loading Balzer’s rapid coating system (RCS) machine at Oerlikon Balzers Ltd. Gurgaon (India). The coating parameters were optimized. The coating thickness was measured along the cross-section for some randomly selected samples as has been reported in Table 5. The thin coatings were obtained and the coatings thickness was observed as 6.1 and 4.2 μm in case of nanostructured TiAlN and AlCrN coatings, respectively. The surface appearance of nanostructured TiAlN coating was violet grey in color and light grey in case of nanostructured AlCrN coating (Figure 2). Figure 3 depicts the optical micrographs of the nanostructured thin coatings. The coatings were dense and have uniform microstructure. It is evident from the microstructure that the coatings contain some pores and inclusions (Figure 3). The negligible porosity values for as-coated nanostructured thin TiAlN and AlCrN coatings were observed, which were less than 0.5% (Table 5).

In case of conventional thick TiAlN and AlCrN coatings, the plasma spray coatings were obtained at Anod Plasma Ltd. Kanpur (India) using a 40 kW Miller Thermal Plasma Spray apparatus. The self-disintegration of thicker coatings usually restricts the thickness of the coatings [17]. The coating parameters were optimized. In the present study, it was possible to obtain a thickness in range of 150–200 μm for the Ti-Al and Al-Cr coatings. After coating deposition process, the gas nitriding was done in lab in order to obtain hard metal nitride coatings. The coating thickness was measured along the cross-section for some randomly selected samples as has been reported in Table 6. The thick coatings were obtained, and the coatings thickness was observed as 172 and 166 μm in case of conventional thick TiAlN and AlCrN, coatings respectively.

The surface appearance of conventional TiAlN and AlCrN coatings was grey with some bluish shining (Figure 2). The surface of conventional thick coatings was rough. The measured porosity of plasma sprayed and gas nitrided coatings is given in Table 6. The measured values of porosity (2.00–4.30%) for as-sprayed conventional Ti-Al and Al-Cr coatings are almost in close agreement with the findings of Chen et al. [18], Erickson et al. [19], Hidalgo et al. [20, 21], Singh et al. [22], and Sidhu et al. [17, 23] for thermal plasma sprayed coatings, whereas after gas nitriding negligible porosity values were observed (Table 6), which were found to be less than 0.6% (Table 6). This may be due to the reason that gas nitriding process may have eliminated the microstructural inhomogeneities due to filling of pores and voids by nitrogen. Figure 3 depicts the optical micrographs of the conventional thick coatings. In case of conventional thick coatings (Figures 3(c) and 3(d)), the massive microstructure could be observed with irregularly shaped grains.

XRD diffractograms for nanostructured and conventional TiAlN and AlCrN coated ASTM-SA210 Grade A-1 boiler steel are depicted in Figure 4 on reduced scale. The phases identified by XRD analysis for nanostructured thin TiAlN coating are TiN and AlN. The phases analyzed are also in agreement with that reported by Yoo et al. [24], Falub et al. [25], and Man et al. [26]. Further, in case of nanostructured AlCrN coating, the prominent phases are CrN and AlN which are in agreement with the findings of Reiter et al. [27] and Endrino et al. [28]. The grain size (Table 1) of the nanostructured thin coatings was estimated from Scherrer formula [29] as follows: where , , and are the X-ray wavelength (1.54056°A), Bragg diffraction angle, and line width at half maximum, respectively. The calculated grain size for nanostructured thin TiAlN and AlCrN coatings was 16 and 26 nm, respectively. Oerlikon Balzers Ltd. Gurgaon (India) has provided the data regarding hardness of the as-coated nanostructured TiAlN and AlCrN coatings (Table 5). The coated layer on the steel substrate has provided higher hardness as compared to the substrate. In particular, nanostructured TiAlN coating showed higher hardness value than nanostructured AlCrN coating.

Figure 5 shows the AFM surface morphology (2D and 3D) of the nanostructured thin TiAlN and AlCrN coatings deposited on ASTM-SA210 Grade A-1 steel. The surface roughness and particle size in the coatings were also provided by AFM analysis, which are reported in Table 5. As the axis scale indicates, the overall roughness of the nanostructured TiAlN coating (Figure 5(b)) is less than that of AlCrN coating (Figure 5(d)). The surface roughness in case of nanostructured TiAlN coating was observed to be 3.75 nm and 6.10 nm in case of nanostructured AlCrN coating (Table 5). The nanostructured thin TiAlN coating had shown smaller particle size (18 nm) as compared to nanostructured thin AlCrN coating (28 nm). The particle size determined by AFM analysis is in good agreement with the results obtained from Scherrer formula (as reported previously). The coating surface was very rough in case of conventional thick TiAlN and AlCrN coatings due to the presence of melted/partially melted particles, and the roughness was found to be in the range of 10.35–15.13 μm and 11.84–15.23 μm, respectively. The centre line average (CLA) method was used to obtain the values.

Further, the main phases identified for the conventional thick TiAlN coating are Al2O3, TiN, Ti3Al, and AlN and small peaks of TiO2 and Fe2O3 as depicted in Figure 4. The phases identified in case of conventional thick AlCrN coating are CrN, AlN, and Al2O3 with minor peaks of Cr2O3 (Figure 4). The presence of metal nitride phases indicates that the gas nitriding process has successfully produced the desired coatings. Further, the phases analyzed are also in agreement with that reported by Adachi and Nakata [30]. They have worked on Ti, Al, and Ti-Al based coatings under various conditions, that is, air and/or nitrogen environment by plasma spraying technique. Further, they have reported that the X-ray diffraction pattern for Ti-50 mass% Al mixed powder sprayed coatings detected Al, and TiN0.3, Ti(N,O) and peaks of synthesized phase of Ti3Al. The sprayed Ti coating had a porous structure and included cracks and pores in high density. The sprayed Al coating had a dense microstructure. And the sprayed Ti-50 mass% Al coatings had a dense laminated structure composed of Ti compounds phase and Al phase. According to them, the formula of Ti3Al formation is given by where is the Gibbs energy of Ti3Al formation (Jmol−1). That is, from the view of the thermodynamics, Ti3Al can be easily formed from Ti with Al. The pressures of O2 and N2 in the atmosphere are much higher than the equilibrium pressure O2 and N2 to form Ti3Al from TiO with Al and TiN with Al [30]. So, Ti3Al cannot be formed thermodynamically from TiO with Al or TiN with Al under the condition of spraying in the air atmosphere. This phenomenon indicates that Ti3Al would be synthesized from Ti and Al particles dynamically during flight [30]. The reaction would proceed at the interface of the Ti particle contacted with the Al particle. The formulas of compounds formation can be described as follows: Conclusively, Adachi and Nakata [30] have reported that the formation of the Ti-Al sprayed coating on the substrate would proceed as follows. At first, the compounds of Ti oxide and nitride in the fused particles would be solidified almost as soon as they adhere to the substrate, as the melting points of TiO and TiN are 2023 K and 3223 K, respectively, which are much higher than that of Al, 933 K. Then, cracks and pores between the Ti compound layers would be filled with the melting Al particles, and the coating finally became solidified as a whole.

Hardness is the most frequently quoted mechanical property of the coatings [31]. The observed microhardness values (Figure 6) for the conventional coatings are within the range of microhardness values reported for plasma coatings by Adachi and Nakata [30], Vuoristo et al. [32], Chen and Hutchings [33], and Westergård et al. [34]. Microhardness plots (Figure 6) indicate some increase in the microhardness of substrate steel at the substrate coating interface. The hardening of the substrates as observed in the current study might have occurred due to the high-speed impact of the coating particles during plasma spray deposition. The effect has also been reported by Hidalgo et al. [20, 21, 35, 36] and Sidhu et al. [17, 23]. The observed nonuniformity in the hardness values along the thickness of the coatings may be due to the microstructural changes along the cross-section of the coatings [37]. Moreover, the microhardness and other properties of the thermal spray coatings are anisotropic because of their typical splat structure and directional solidification [31].

The bond strength of the conventional thick TiAlN and AlCrN coatings was measured on three specimens as per ASTM standard C633-01. The coatings failed at the substrate-coating interface while they remain attached to the adhesive (Figure 7). Average bond strength of 68.74 MPa and 54.69 MPa was observed in case of conventional TiAlN and AlCrN coatings, respectively (Table 6). The bond strength in case of conventional TiAlN coatings (68.74 MPa) is in good agreement (slightly more) with the results reported by Adachi and Nakata [30] regarding their work based on plasma sprayed Ti-Al coatings (60 MPa).

FE-SEM micrographs along with EDS spectrum that reveal the surface morphology of the nanostructured and conventional TiAlN and AlCrN coated ASTM-SA210 Grade A-1 boiler steel are shown in Figure 8. Surface EDAX analysis is supported by XRD (Figure 4) and X-ray mapping analysis (Figure 9) in all coatings. The presence of Ti, Al, and N with negligible amount of Fe (in nanostructured TiAlN coating), Al, Cr, and N along with small amount of Fe and oxygen (in nanostructured TiAlN coating) the higher concentration of Ti and Al in the coating along with some amount of N and oxygen (in conventional TiAlN coating) and Al and Cr along with N and oxygen (in conventional AlCrN coating); is revealed by surface EDAX analysis (Figure 8). Also, the XRD analysis (Figure 4) indicates the presence of the oxide phases in the coatings, that is, Al2O3, TiO2, and Fe2O3 in case of conventional TiAlN coating and the presence of Al2O3 and Cr2O3 in case of conventional AlCrN coatings. According to Bluni and Mardar [38] the oxides may have formed due to the in-flight oxidation during spraying process and/or preexisting in the feed material. The latter reason for the oxides formation in the structure of coatings under study looks to be more relevant as the chances of inflight oxidation are meager in case of the shrouded plasma spraying.

Deshpande et al. [39] proposed that, during in-flight oxidation, a layer of oxide is formed on the molten particle due to chemical reactions between the surface of the liquid phase and oxygen or due to diffusion of oxygen into the liquid. The turbulent mixing of the liquid part of the powder particle during its flight destroys the surface layer of oxides and causes the oxides to be distributed more uniformly through the bulk volume of the particle. However, when temperature of the particle starts dropping during later part of the flight, these oxides tend to solidify and a thin oxide shell would be formed around the droplet.

The oxidation time during thermal spray coating is short typically less than 0.01 s and can occur in either the solid or molten state. The oxidation of coatings is not always harmful; it is equally important to control and understand the different aspects of oxidation of coatings; therefore, it is important to find an optimum level for oxidation of coatings [4042]. The diffusion of Fe from the substrate to the coating (in conventional coatings) was identified by XRD and X-ray-mapping analysis. This type of diffusion of the base metal component into the coating has also been observed by Wang et al. [43]. They have reported the penetration of Co from the base alloy to the coating after heat treatment of coatings for 2 hrs at 1050°C.

5. Conclusions

The nanostructured thin TiAlN and AlCrN coatings (by physical vapour deposition process at Oerlikon Balzers Ltd. Gurgaon, India) and conventional thick TiAlN and AlCrN coatings (by plasma spraying process at Anod Plasma Ltd. Kanpur, India; followed by gas nitriding process) were successfully deposited on ASTM-SA210 Grade A-1 boiler steel. The coatings were characterized for their microstructural features and hardness in present work. The following observations were made based on the present study.(1)The nanostructured thin TiAlN and AlCrN coatings exhibited negligible porosity values for as-coated, which were less than 0.5%. The conventional TiAlN and AlCrN coatings showed higher porosity values (2.00–4.30%) for as-sprayed conventional Ti-Al and Al-Cr coatings which after gas nitriding were found to be less than 0.6%.(2)The phases identified by XRD analysis for nanostructured thin TiAlN coating are TiN and AlN. Further, in case of nanostructured AlCrN coating, the prominent phases are CrN and AlN. The main phases identified (by XRD analysis) for the conventional thick TiAlN coating were Al2O3, TiN, Ti3Al, ands AlN and small peaks of TiO2 and Fe2O3. The phases identified in case of conventional thick AlCrN coating were CrN, AlN, and Al2O3 with minor peaks of Cr2O3. The presence of metal nitride phases indicates that the gas nitriding process has successfully produced the desired coatings.(3)The grain size (calculated by Scherrer formula from XRD plot) for nanostructured thin TiAlN and AlCrN coatings was 16 and 26 nm, respectively. The particle size determined by AFM analysis is in good agreement with the results obtained from Scherrer formula. From AFM analysis, the particle size observed for nanostructured thin TiAlN and AlCrN coatings was 18 nm and 28 nm respectively. (4)The surface roughness in case of nanostructured TiAlN coating was observed as 3.75 nm and 6.10 nm in case of nanostructured AlCrN coating, as observed by AFM analysis. The coating surface was very rough in case of conventional thick TiAlN and AlCrN coatings due to the presence of melted/partially melted particles, and the roughness was found to be in the range of 10.35–15.13 μm and 11.84–15.23 μm, respectively. The centre line average (CLA) method was used to obtain the values. (5)A good adhesion of the conventional thick TiAlN and AlCrN coatings was evident from bond test results. Average bond strength of 68.74 MPa and 54.69 MPa Psi was observed in case of conventional TiAlN and AlCrN coatings, respectively.