University of Birmingham Effects of annealing temperatures on the morphological, mechanical, surface chemical bonding, and solar selectivity properties of sputtered TiAlSiN thin films Rahman, M. Mahbubur; Jiang, Zhong-tao; Zhou, Zhi-feng; Xie, Zonghan; Yin, Chun Yang; Kabir, Humayun; Haque, Md. Mahbubul; Amri, Amun; Mondinos, Nicholas; Altarawneh, Mohammednoor DOI: 10.1016/j.jallcom.2016.02.077 License: Creative Commons: Attribution-NonCommercial-NoDerivs (CC BY-NC-ND) Document Version Peer reviewed version Citation for published version (Harvard): Rahman, MM, Jiang, Z, Zhou, Z, Xie, Z, Yin, CY, Kabir, H, Haque, MM, Amri, A, Mondinos, N & Altarawneh, M 2016, 'Effects of annealing temperatures on the morphological, mechanical, surface chemical bonding, and solar selectivity properties of sputtered TiAlSiN thin films', Journal of Alloys and Compounds, vol. 671, pp. 254-266. https://doi.org/10.1016/j.jallcom.2016.02.077 Link to publication on Research at Birmingham portal Publisher Rights Statement: Eligibility for repository checked: 19/04/16 General rights Unless a licence is specified above, all rights (including copyright and moral rights) in this document are retained by the authors and/or the copyright holders. 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Mahbubul Haque, Amun Amri, Nicholas Mondinos, Mohammednoor Altarawneh PII: S0925-8388(16)30346-2 DOI: 10.1016/j.jallcom.2016.02.077 Reference: JALCOM 36688 To appear in: Journal of Alloys and Compounds Received Date: 21 December 2015 Revised Date: 5 February 2016 Accepted Date: 8 February 2016 Please cite this article as: M.M. Rahman, Z.-T. Jiang, Z.-f. Zhou, Z. Xie, C.Y. Yin, H. Kabir, M.M. Haque, A. Amri, N. Mondinos, M. Altarawneh, Effects of annealing temperatures on the morphological, mechanical, surface chemical bonding, and solar selectivity properties of sputtered TiAlSiN thin films, Journal of Alloys and Compounds (2016), doi: 10.1016/j.jallcom.2016.02.077. This is a PDF file of an unedited manuscript that has been accepted for publication. As a service to our customers we are providing this early version of the manuscript. The manuscript will undergo copyediting, typesetting, and review of the resulting proof before it is published in its final form. Please note that during the production process errors may be discovered which could affect the content, and all legal disclaimers that apply to the journal pertain. ACCEPTED MANUSCRIPT 1 Effects of annealing temperatures on the morphological, mechanical, 2 surface chemical bonding, and solar selectivity properties of sputtered 3 TiAlSiN thin films 4 T 5 M. Mahbubur Rahman1*, Zhong-Tao Jiang1*, Zhi-feng Zhou2, Zonghan Xie3, Chun Yang 6 Yin4, Humayun Kabir5, Md. Mahbubul Haque6, Amun Amri7, Nicholas MondPinos1, 7 Mohammednoor Altarawneh8 I R 8 1 Surface Analysis and Materials Engineering Research Group C 9 School of Engineering & Information Technology, Murdoch University, Murdoch, Western 10 Australia 6150, Australia S 11 2Department of Mechanical and Biomedical Engineering, City University of Hong Kong, U 12 Kowloon, Hong Kong, China 13 3School of Mechanical Engineering, University of ANdelaide, SA 5005, Australia 14 4School of Science and Engineering, Teesside UniveArsity, Borough Road, Middlesbrough, 15 TS1 3BA, United Kingdom M 16 5School of Metallurgy and Materials, University of Birmingham, Edgbaston, Birmingham 17 B15 2TT,D United Kingdom 18 6Materials Science Division, AtomEic Energy Centre Dhaka, Dhaka 1000, Bangladesh T 19 7Department of Chemical Engineering, Riau University, Pekanbaru, Indonesia P 20 8School of Engineering & Information Technology, Murdoch University, Murdoch, Western 21 Australia 6150, Australia E 22 *Corresponding Authors: [email protected] (M.M. Rahman) C 23 [email protected] (Z.-T. Jiang) 24 C 25 26 ABSTRACT A 27 Quaternary sputtered TiAlSiN coatings were investigated for their high temperature structural 28 stability, surface morphology, mechanical behaviors, surface chemical bonding states, solar 29 absorptance and thermal emittance for possible solar selective surface applications. The 30 TiAlSiN films were synthesized, via unbalanced magnetron sputtered technology, on AISI M2 31 steel substrate and annealed at 500 °C - 800 °C temperature range. SEM micrographs show 32 nanocomposite-like structure with amorphous grain boundaries. Nanoindentation analyses ACCEPTED MANUSCRIPT 33 indicate a decrease of hardness, plastic deformation and constant yield strength for the 34 coatings. XPS analysis show mixed Ti, Al and Si nitride and oxide as main coating 35 components but at 800 °C the top layer of the coatings is clearly composed of only Ti and Al 36 oxides. Synchrotron radiation XRD (SR-XRD) results indicate various Ti, Al and Si nitride T 37 and oxide phases, for the above annealing temperature range with a phase change occurring 38 with the Fe component of the substrate. UV-Vis spectroscopy, FTIR spectroscPopy studies 39 determined a high solar selectivity, s of 24.6 for the sample annealed at 600 °C.I Overall results 40 show good structural and morphological stability of these coatings at tempeRratures up to 800 41 °C with a very good solar selectivity for real world applications. C 42 Keywords: magnetron sputtering; thin film coatings; optical properties; solar absorptance; S 43 solar emittance; selective solar surface. U 44 1. Introduction N 45 Transition metal nitride based quaternary TiAlSiN coatings are attractive candidates A 46 as cutting tools, protective and decorative coatings due to their many outstanding properties M 47 [1]. In recent years they have seen significant interest as solar selective absorbers for 48 harvesting solar energy in various applications such as thermal solar collectors, solar steam 49 generators and steam turbines for prodDucing the electricity at mid and mid-to high 50 temperatures [2-13]. A good selective surface must have high absorptance (α) in the visible E 51 spectrum up to 2.5 µm and low emittance (ε) in the infra-red (IR) region ≥ 2.5 µm at the T 52 operating temperatures. In recent years, transition metal nitride based tandem coatings (e.g., 53 TiAlN/AlON, and TiAl/TiAlPN/TiAlON/TiAlO) have been suggested for use in solar selective 54 surfaces to be used in photothermal applications [4, 14]. Barshilia et al. [15] developed a high E 55 thermal stable TiAlN/TiAlON/Si N tandem absorber on a copper substrate for high 3 4 C 56 temperature solar selective applications that exhibited an absorptance of 0.958 and an 57 emittance of 0.0C7. Until now these materials have not been commercially produced [4, 11, 58 16]. TransitAion metal oxides based thin film coatings with good optical properties have been 59 also developed for solar selective surface applications [17-22]. 60 Most of the solar selective coatings exhibit good stability in a vacuum but in air they 61 have very limited thermal stability. However, in a high temperature or for long period 62 application purposes, these solar selective absorbers should have stable structural 63 configuration minimal degradations. The oxidation resistance behaviour of these coatings is 64 also very important as they are frequently exposed at high temperature atmospheres in air. ACCEPTED MANUSCRIPT 65 The addition of Al and Si to the TiN coatings increases their oxidation resistance by forming 66 oxide layers around the surface which eventually work as a barrier for further oxygen 67 penetrations at high temperatures. The formation of amorphous phases also provides better 68 stability against degradation, corrosion and oxidation than that of crystalline metallic nitride T 69 phases. TiAlSiN coatings provide good thermal stability at temperatures above 800 °C [26, 70 27]. These coatings have been explored mostly for their extraordinary mechanicalP properties, 71 but as applications in solar selective surfaces in thermal collector devices Iare relatively 72 unexplored [28-31]. R 73 The synchrotron radiation X-ray diffraction (SR-XRD techniqueC is successfully used 74 to probe the crystalline and electronic structure of various systems in a wide range of fields S 75 such as physics, chemistry, environmental sciences, materials sciences, biology, medicine, U 76 and geophysics. The SR-XRD offers many advantages over the conventional laboratory 77 based XRD techniques such as: highly collimated and inteNnse photon beams, photon-energy 78 tune ability, exceptional photon wavelength resolutionA (∆λ/λ ≈ 2 × 10-4), polarization control, 79 coherence, very high signal-to-noise and signal-to-background ratio. The synchrotron M 80 techniques are extensively used in the identification of phases in compounds and unknown 81 structural forms developed during the synth esis processes of the films. In recent years these D 82 techniques successfully investigated the local electronic structure of metal nitride thin films 83 in pure and doped states [23-25]. E 84 To the best of our knowTledge, investigations on structural thermal stability and 85 oxidation resistance behaviours of these coatings via SR-XRD technique are yet to be P 86 established. This study addresses the temperature dependent surface morphology, mechanical E 87 properties, surface chemical bonding states, high temperature solar selective behaviours, and C 88 high temperature structural stability of magnetron sputtered TiAlSiN coatings via 89 mechanical, SEMC, XPS, UV-Vis and FTIR, and SR-XRD techniques. 90 A 91 2. Experimental techniques 92 2.1 Film deposition process 93 TiAlSiN films were deposited onto AISI M2 tool steel substrates via a closed field 94 unbalanced magnetron sputtering system (UDP650, Teer Coating Limited, Droitwich, 95 Worcestershire, UK). The magnetron sputtered system is equipped with a four-target ACCEPTED MANUSCRIPT 96 configuration. Before coating, the substrates were ultrasonically cleaned in an acetone and 97 methanol solution and then dried using high purity nitrogen gas. A pressure of 0.24 Pa was 98 maintained in the chamber throughout the deposition process. Prior to synthesizing the 99 samples, all of the targets were cleaned properly and the steel substrates were safeguarded by T 100 shutters through the magnetrons. In order to achieve a homogeneous film thickness, the 101 substrate was rotated at a speed of 10 rpm throughout the synthesis process. TheP substrates 102 were sputter cleaned with Ar plasma at a bias of -450 V for 30 minutes. The Icoatings were 103 deposited in an Ar+N mixed gas atmosphere. The partial pressure of Ar anRd N were 0.133 2 2 104 Pa and 0.106 Pa throughout the deposition processes. The bias currents for Ti, Al and Si C 105 target were 5 A, 7 A, and 5 A, respectively. The final products were then annealed at 500, 106 600, 700 and 800 °C. Details of the deposition conditions of TiAlSSiN coatings are displayed 107 in Table 1. U N 108 2.1 Characterisations A 109 Scanning electron microscopy (SEM) was conducted to determine the surface 110 morphology of the thin film coatings with a high Mresolution microscope (SEM, PHILIPS XL 111 20, Eindhoven, The Netherlands). A secondary electron (SEI) detector was used to 112 characterize the overall surface morphologDy of thin film structures. The SEM machine was 113 operated at 25 kV. The samples were glued with double sided carbon tape affixed to the E 114 sample holders. 115 T 116 A depth-sensing indentation system (Ultra-Micro Indentation System, UMIS-2000, P 117 CSIRO, Australia) equipped with a Berkovich indenter was used to measure the Young’s 118 modulus and hardness ofE the coatings. The indenter tip was calibrated by conducting single- 119 cycling indentation tests on fused silica (a standard material having a known modulus of 72 C 120 GPa) at different loads. Load–unload tests were run in a closed-loop under load control to C 121 determine the mechanical properties of the samples. A maximum load of 20 mN was applied 122 in 10 incremAents. The loading rate set to 2.5 mN/s represents the static response of the 123 materials. Following each increment there were 10 decrements, from which the Young’s 124 modulus and hardness were calculated. Five indentation tests were performed on each 125 specimen. The load vs displacement response obtained by nanoindentation is a very powerful 126 technique for analysing mechanical properties. The elastic behaviour of, and deformation 127 mechanisms within, the coating systems can be realized by analysing the nanoindentation 128 data. In order to investigate the thermal stability of the sputtered films, mechanical hardness ACCEPTED MANUSCRIPT 129 of the coatings was tested with the samples before annealing and after being annealed 130 between 500 °C and 800 °C in steps of 100 °C in air atmosphere. 131 132 The XPS data will reveal information on chemical structure, elemental compositions 133 and bonding states in the outermost 5 nm surface of the films. The XPS measurements of the T 134 TiAlSiN coatings were taken using an XPS (Kratos Axis Ultra XPS spectrometer, P 135 Manchester, UK) machine operating with an Al-Kα monochromatic radiation (hν = 1486.6 I 136 eV) source with a power of ~10 mA and ~15 kV. The XPS machine was also equipped with a R 137 cold stage, and an Ar ion gun for etching the coatings. The samples were mounted on a steel 138 sample holder and put in the analysis chamber where the pressure was Creduced to 2.9 × 10-9 139 Torr. The XPS survey spectra were collected before etching, and after 6 minutes etching. Ar S 140 ion sputtering was used for etching the films. Etching was done to remove any surface oxide U 141 layers and to reduce the Ti4+ ions in order to lower oxidation states. The high resolution XPS 142 data was recorded after a 6 minute Ar+ sputtering. The typNical high resolution XPS core level 143 spectra of TiAlSiN samples before and after being annAealed show Ti2p, Al2p, Si2p, N1s and 144 O1s energy regions. Information on the existence of various chemical bonding states was M 145 acquired by subtracting the background with the Shirley’s method and deconvoluting the 146 spectra with curve-fitting methods using CA SA XPS software (version 2.3.1.5) [32]. D 147 The optical properties of the thin film coatings were analysed by measuring the 148 optical reflectance as a function of waEvelength from ultraviolet through the visible to infrared 149 range of the solar spectrum via UV-Vis and FTIR spectrometers. A double-beam UV–Vis T 150 spectrophotometer (Model: UV-670 UV-Vis spectrophotometer, JASCO, USA) equipped P 151 with a unique, single monochromator design covering a wavelength range from 250 to 2500 152 nm was used to measure Ethe solar absorptance of the coatings. The monochromator itself was 153 designed with 1200 grooves/mm grating and a photo multiplier tube (PMT) detector. A C 154 PERKIN Elmer Spectrum 100 FTIR Spectrometer (USA) was used for measuring the C 155 reflectance, R(λ), of the coatings in the wavelength range of 2.5 to 15 µm. Using the R(λ) data 156 the solar abAsorptance (a ) and the solar emittance (e) of a material can be conveniently 157 estimated [20]. For a range of solar wavelengths, the total solar absorptance, α is defined as a 158 weighted fraction between absorbed radiation and incoming solar radiation (I ), while sol 159 thermal emittance, ε is defined as a weighted fraction between emitted radiation and the 160 Planck black-body distribution (I ). The figure of merit of a selective surface is expressed in p 161 term of a parameter known as the selectivity, s. The solar selectivity of a material is defined ACCEPTED MANUSCRIPT 162 by the ratio of the solar absorptance, α to the thermal emittance, ɛ, with expression (s) given 163 in Ref. [20]. 164 The SR-XRD measurements of the TiAlSiN coatings were carried out with the 165 powder diffraction (PD) beamline 10-BM-1 at the Australian Synchrotron, in Melbourne. The T 166 PD beamline operated at 2.5 GeV and used a bending magnet source. A continuous spectrum P 167 of photons were generated in the range 5–30 keV with a maximum flux of about 1013 I 168 photons/sec and a beam size of 1 mm (W) × 8 mm (L) x 1 mm (H). The general beam size of R 169 the sample for the focused and unfocussed beam arrangements was 0.5 mm × 0.5 mm and 5 170 mm × 2 mm respectively. An X-ray wavelength of 0.8265 Å, estimated Cwith a LaB6 standard 171 NIST 660a, was used for the measurements. The high temperature system was an Anton Parr S 172 HTK20 furnace. The furnace was calibrated and monitored by a thermocouple and the U 173 heating and cooling cycles were remotely controlled via a computer interface. The high 174 resolution XRD data was acquired at room temperature, 50N0 °C, 600 °C, 700 °C, and 800 °C. 175 A MYTHEN II microstrip detector system was used tAo record the high resolution XRD data 176 in the range of 2θ = 15° to 35° in steps of 0.02°. At each detector setting SR-XRD data was M 177 acquired for a period of 5 minutes. Data collection was started after a 3 min thermal 178 equilibration period at which the control sen sor had reached the set temperature. The acquired D 179 data was processed with PDViPeR software for further analysis. E 180 3. Results and discussion 181 3.1 Surface morphology of TTiAlSiN films 182 SEM images of sputtered TiAlSiN coatings before annealing and after being annealed P 183 at 500-800 °C in steps of 100 °C are presented in Fig. 1. SEM examination of the E 184 microstructure showed nanocomposite-like structure deformed by formation of an amorphous C 185 phase and facilitated by fine grains. As the annealing temperature progresses from 500 to 600 186 °C, there originaCted some random pores around the surface of the coatings together with non- 187 uniform grains. At the same time, the surface morphology and shape of the grains of the films A 188 were altered together with the rise in irregular mound like structures around the film’s 189 surfaces. Further inspection confirms that the higher surface roughness is attained by the 190 coatings as the annealing temperature is increased. This surface roughness hinders the 191 diffusion of titanium and nitrogen atoms and slows down their diffusions, helps to grain 192 growth and develop amorphous like structures around the grain boundaries. However, the 193 new phase is extremely small in size and cannot be detected by either XRD or SEM. Because 194 of this lower mobility, the crystallization process is disrupted and disordering is enhanced for ACCEPTED MANUSCRIPT 195 further amorphization by Si N phases around the boundaries. This amorphous grain 3 4 196 boundaries influence the optical properties of these coatings [33]. The annealed films 197 exhibited nanolayers which are observed as darker and lighter contrasts in the SEM 198 micrographs together with the fine-grained structure of the coatings. This is due to the T 199 systematic increase on the oxide thickness growing on top of the coating with the rise in 200 annealing temperatures. The oxides layers which are observed are composed ofP Al2O3 and 201 SiO2 at the outermost layer of the coating followed by TiO2 layers (as seen inI XPS studies). 202 These nano-sized protective layer formed on the nitride film hinders the diffRusion of oxygen 203 into the coating due to their small size and polycrystalline nature. These nanolayers did not C 204 vanish or alter their structure as a consequence of the heat treatment; rather, they seem to be 205 very stable [34]. The dense and closely packed structures show Smore stability as selective 206 surfaces at high temperatures. These kind of sputtered coatingsU are more reliable than similar 207 coatings with large columns and open pores [35]. These microstructural features have N 208 substantial impacts on the residual stress and deformation mechanisms in the coatings and A 209 could assist with the interpretation of mechanical hardness of these coatings. 210 M 211 3.2 Mechanical properties of TiAlSiN coatings before annealing and after being 212 annealed D 213 The hardness, H and Young’s modulus, E values of the sputtered TiAlSiN coatings E 214 before and after annealing are presented in in Fig. 2. Table 2 represents the hardness, elastic T 215 modulus, Yield strength and corresponding plastic deformation resistance of the TiAlSiN 216 coatings as acquired from theP nanoindentation measurements. Before annealing, the TiAlSiN 217 coating showed a hardneEss of 28.1 ± 0.6 GPa and an elastic modulus of 369 ± 9 GPa. Similar 218 values for hardness and modulus have been reported in other studies [36-38]. C 219 220 The high hardness and high elastic modulus of TiAlSiN coatings before annealing C 221 arises due to the biaxial compressive stress developed by high energetic ions bombardment A 222 during the coating deposition. Effects of biaxial compressive stress on the hardness of 223 superhard multilayer coatings were examined by Veprek et al [39-41]. An increase in the 224 development of the intergranular amorphous phase in the nanocomposite matrix leads to a 225 definite enhancement of the hardness of the coatings. This is also true of the elastic modulus 226 values. At nano-scale level, the obstruction of dislocation movements and the nonappearance 227 of dislocations also contribute to enhance the hardness of the coatings [42]. The dissolution 228 of Al and Si atoms in the TiN crystallites produce solid solutions that are also responsible for ACCEPTED MANUSCRIPT 229 the greater hardness of these coatings [43, 44]. In addition, the grain boundary strengthening 230 at interphase boundaries also predominate to a higher hardness in the films [37, 45]. 231 According to Veprek [39-41], a superhard microstructure with high elasticity and thermal 232 stability can be formed by fine nanocrystallites (<10 nm) enclosed by a thin amorphous phase T 233 (<1 nm) along with a strong boundary between the amorphous and crystalline phases. This 234 interface successfully hinders the grain boundary sliding’s, the formation of dislocPations and 235 their movements, and the spread of cracks. Generally a hard material hIas high wear 236 resistance. The material’s hardness and elastic modulus are also related to thRe wear behavior 237 [46]. It is known that the wear of a material is coupled with the elastic limit of materials that C 238 define the ability of a material to deform under an applied stress and regain its initial state 239 without being deformed permanently [46]. Experimental valuSe of the elastic limit is 240 expressed by the H/E ratio. The H3/E2 ratio, which is known as Uthe plastic deformation factor, 241 indicates the coating’s resistance to plastic flow [47]. Each of the parameters play an essential N 242 role in the coating wear behaviors. The linear decrease of H, H/E and H3/E2 are well A 243 correlated with the reduction of wear resistance of TiAlSiN coatings during high temperature 244 annealing. A high value of the H3/E2 ratio of a coMating means that it offers high resistance to 245 plastic deformation. This high value of the H3/E2 ratio is also associated with hindering 246 dislocation formation or movement due toD nano-grains and the solid impeding of the crack 247 dissemination in the amorphous Si N phase [48]. From an engineering application 3 4 E 248 viewpoint, coating hardness must be accompanied by appropriate toughness and the ability of 249 a material to absorb energy underT an applied stress until fracture [49]. Musil and Jirout [50] 250 reported their findings that resistance against crack formation of thin film coatings increases P 251 with increasing H3/E2 ratio. From Table 2, it can be seen that both the hardness and elastic E 252 modulus strongly depend on the annealing temperatures. The hardness decrement of the C 253 TiAlSiN coatings at elevated annealing temperatures may result from diverse mechanisms. 254 Since the coatinCgs were heated in air, the composition at the surface is expected to change 255 due to oxidation, and therefore, it is reasonable to have lower hardness as the annealing A 256 temperature is enhanced. At high temperature annealing, the reduction in hardness and elastic 257 modulus values of TiAlSiN coatings may be also ascribed to the softening of steel substrates, 258 changes in composition of the films due to the diffusion, formation of new phases and stress 259 relaxations. High temperature annealing causes grain refinement, and when combined with 260 the formation of point defects, interstitials, biaxial compressive stress, and other effects of the 261 ion bombardment may result in a reduction of hardness and elastic modulus as the 262 temperature is increased. According to Petrov et al. and Barna et al., oxygen and other
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