39 research outputs found
DESARROLLO DE MATERIALES CERÁMICOS AVANZADOS CON ALTAS PRESTACIONES MEDIANTE TÉCNICAS NO CONVENCIONALES DE SINTERIZACIÓN: MICROONDAS
[EN] Microwave material sintering provides many advantages over conventional methods. This is a non-conventional technique, where materials absorb and convert electromagnetic energy into heat. The heating process is very different from other methods where heat is transferred through mechanisms of conduction, radiation and convection. The main advantages of microwave sintering can be summarized into three main points: reducing processing time and production costs, environmental benefits and processing flexibility. Therefore, microwaves are an attractive alternative to other sintering methods.
The main aim of this thesis is to obtain dense lithium aluminosilicate (LAS) ceramics with adequate mechanical performance and exceptional features by the non-conventional sintering technique of microwave heating for specific applications. The high thermal stability of these materials makes them useful for microelectronics, precision optics and aerospace technologies. Mechanical and thermal properties can be improved by microwave sintering technique.
To achieve this goal, the microwave sintering equipment will be optimized in order to obtain solid-state LAS materials and their final properties will be evaluated. As a complimentary phase, the feasibility of improving such properties by the addition of selected second phases, such as alumina and graphene, will be investigated.[ES] La sinterización de materiales por medio de las microondas aporta muchas ventajas frente a los métodos convencionales. Se trata de una técnica no-convencional donde los materiales absorben las ondas electromagnéticas y las transforman en calor. Este proceso es muy diferente de otros métodos, donde el calor es transferido a través de los mecanismos de conducción, radiación y convección. Las principales ventajas de la sinterización por microondas se puede resumir en tres: reducción de tiempos y costes económicos de producción, beneficios medioambientales y flexibilidad del procesado. Por lo tanto, las microondas son una clara alternativa a otros métodos de sinterización.
El objetivo final de esta Tesis Doctoral es la obtención, mediante la técnica de sinterización no convencional de microondas, de materiales cerámicos basados en aluminosilicato de litio (LAS) densos, que reúnan unas prestaciones mecánicas adecuadas y unas funcionalidades excepcionales, para su utilización en aplicaciones específicas. La alta estabilidad térmica de estos materiales los hace idóneos para aplicaciones en el campo de la microelectrónica, la óptica de precisión y la tecnología aeroespacial. Mediante la utilización de las microondas, se pretende mejorar sus propiedades finales, tanto mecánicas como térmicas.
Para lograr este objetivo, se adaptarán los equipos de microondas a la sinterización de los materiales de LAS en estado cristalino y se evaluarán sus propiedades finales. En una última fase, se estudiará la viabilidad de mejorar las propiedades de los materiales obtenidos en la etapa anterior, mediante la adición de segundas fases seleccionadas: alúmina y grafeno.[CA] La sinterització de materials per mitjà de les microones aporta molts avantatges enfront dels mètodes convencionals. Es tracta d'una tècnica no-convencional on els materials absorbeixen les ones electromagnètiques i les transformen en calor. Aquest procés és molt diferent d'altres mètodes, on la calor és transferida per mig dels mecanismes de conducció, radiació i convecció. Els principals avantatges de la sinterització per microones es poden resumir en tres: reducció de temps i costos econòmics de producció, beneficis mediambientals i flexibilitat del processament. Per tant, les microones són una clara alternativa a altres mètodes de sinterització.
L'objectiu final d'aquesta Tesi Doctoral és l'obtenció, mitjançant la tècnica de sinterització no-convencional de microones, de materials ceràmics basats en aluminosilicats de liti (LAS) densos, que reunisquen unes prestacions mecàniques adequades i unes funcionalitats excepcionals, per a la seua utilització en aplicacions específiques. L'alta estabilitat tèrmica d'aquests materials els fa idonis per a aplicacions en el camp de la microelectrònica, l'òptica de precisió i la tecnologia aeroespacial. Mitjançant la utilització de les microones, es pretén millorar les seues propietats finals, tant mecàniques com tèrmiques.
Per a aconseguir aquest objectiu, s'adaptaran els equips de microones a la sinterització dels materials de LAS en estat cristal·lí i s'avaluaran les seues propietats finals. En una última fase, s'estudiarà la viabilitat de millorar les propietats dels materials obtinguts en l'etapa anterior, mitjançant l'addició de segones fases seleccionades: l'alúmina i el grafé.Benavente Martínez, R. (2015). DESARROLLO DE MATERIALES CERÁMICOS AVANZADOS CON ALTAS PRESTACIONES MEDIANTE TÉCNICAS NO CONVENCIONALES DE SINTERIZACIÓN: MICROONDAS [Tesis doctoral]. Universitat Politècnica de València. https://doi.org/10.4995/Thesis/10251/49358TESISPremios Extraordinarios de tesis doctorale
Determinación de la tenacidad a fractura en cerámicas mediante indentación Vickers
En este artículo docente te mostramos una metodología para poder determinar la tenacidad a fractura, KIC, de materiales cerámicos.Borrell Tomás, MA.; Benavente Martínez, R. (2024). Determinación de la tenacidad a fractura en cerámicas mediante indentación Vickers. http://hdl.handle.net/10251/20535
Dense nanostructured zirconia compacts obtained by colloidal filtration of binary mixtures
As starting materials two commercial nanosized zirconias doped with 3 mol% of Y 2O 3 were used: a powder of about 100 nm (TZ3YE, Tosoh, Japan) and a colloidal suspension of about 15 nm (Mel Chemicals, UK). Colloidal stability in water was studied for both zirconias in terms of zeta potential as a function of deflocculant concentration and pH. Concentrated suspensions were prepared by dispersing the powder in the colloidal suspension to solids loadings ranging from 5 to 30 vol.% using a sonication probe to achieve dispersion. The rheological behavior was optimized in terms of solids content, deflocculant content and sonication time. Optimized suspensions with up to 25 vol.% solids showed a nearly Newtonian behavior and extremely low viscosities and maintain stable for long times (days) which is an important drawback of conventional nanoparticle suspensions. Samples obtained by slip casting in plaster moulds were used for dynamic sintering studies and dense, nanostructured specimens were obtained at temperatures of 1300-1400°C.This work has been supported by Spanish Ministry of Science and Innovation (Projects MAT2009-14144-C03-02 and MAT2009-14369-C02-01). R. Moreno thanks to Universidad Politecnica de Valencia for the concession of a grant in the frame of its Programme of Support to R + D (PAID-02-11, R-1752).Benavente Martínez, R.; Salvador Moya, MD.; Alcázar, M.; Moreno, R. (2012). Dense nanostructured zirconia compacts obtained by colloidal filtration of binary mixtures. Ceramics International. 38(3):2111-2117. https://doi.org/10.1016/j.ceramint.2011.10.051S2111211738
Effect of a Powder Mould in the Post-Process Thermal Treatment of ABS Parts Manufactured with FDM Technology
[EN] The post-process thermal treatment of thermoplastics improves their mechanical properties, but causes deformations in parts, making them unusable. This work proposes a powder mould to prevent dimensional part deformation and studies the influence of line building direction in part deformations in a post-process thermal treatment of 3D printed polymers. Two sets of ABS (acrylonitrile butadiene styrene) test samples manufactured by fused deposition modelling (FDM) in six different raster directions have been treated and evaluated. One set has been packed with a ceramic powder mould during thermal treatment to evaluate deformations and mould effectiveness. Thermogravimetric tests have been carried out on ABS samples, concluding that the thermal treatment of the samples does not cause degradations in the polymeric material. An analysis of variance (ANOVA) was performed to study internal building geometry and mould influence on part deformation after the thermal treatment. It can be concluded that powder mould considerably reduces dimensional deformations during the thermal treatment process, with length being the most affected dimension for deformation. Attending to the length, mould effectiveness is greater than 80% in comparison to non-usage of moulding, reaching 90% when the building lines are in the same direction as the main part.This research received partial funding from the Government of Spain under the project PID2019-108807RB-I00.Lluch-Cerezo, J.; Benavente Martínez, R.; Meseguer, M.; García Manrique, JA. (2021). Effect of a Powder Mould in the Post-Process Thermal Treatment of ABS Parts Manufactured with FDM Technology. Polymers. 13(15):1-16. https://doi.org/10.3390/polym13152422S116131
Multilayer and particle size-graded YSZ coatings obtained by plasma spraying of micro- and nanostructured feedstocks
This work was supported by the Spanish Ministry of
Science and Innovation (Project MAT2012-38364-C03)
and the Research Promotion Plan of Universitat Jaume I,
action 3.1 (Ref. PREDOC/2009/10), and it has been
co-funded by the European Regional Development Fund
(ERDF). The authors also thank the SCIC of Universitat
Jaume I for the FEG-SEM observationsCarpio, P.; Bannier, E.; Salvador Moya, MD.; Benavente Martínez, R.; Sanchez Vilches, E. (2014). Multilayer and particle size-graded YSZ coatings obtained by plasma spraying of micro- and nanostructured feedstocks. Journal of Thermal Spray Technology. 23(8):1362-1372. https://doi.org/10.1007/s11666-014-0143-9S13621372238D.R. Clarke and S.R. Phillpot, Thermal Barrier Coatings Materials, Mater. Today, 2005, 8, p 22-29N.P. Patdure, M. Gell, and E.H. Jordan, Thermal Barrier Coatings for Gas-Turbine Engine Applications, Science, 2002, 296, p 280-284L. Pawlowski, Finely Grained Nanometric and Submicrometric Coatings by Thermal Spraying: A Review, Surf. Coat. Technol., 2008, 205(43), p 18-28R.S. Lima and B.R. Marple, Thermal Spray Coatings Engineered from Nanostructured Ceramic Agglomerated Powders for Structural, Thermal Barrier and Biomedical Applications: A Review, J. Therm. Spray Technol., 2007, 16(1), p 40-63P. Fauchais, G. Montavon, R.S. Lima, and B.R. Marple, Engineering a New Class of Thermal Spray Nano-Based Microstructures from Agglomerated Nanostructured Particles, Suspensions and Solutions: An Invited Review, J. Phys. D, 2011, 44(9), 93001, p 1-131M. Gell, E.H. Jordan, Y.H. Sohn, D. Goberman, L. Shaw, and T.D. Xiao, Development and Implementation of Plasma Sprayed Nanostructured Ceramic Coatings, Surf. Coat. Technol., 2001, 146-147, p 48-54R.S. Lima and B.R. Marple, Nanostructured YSZ Thermal Barrier Coatings Engineered to Counteract Sintering Effects, Mater. Sci. Eng. A, 2008, 485, p 182-193H. Chen, X. Zhou, and C. Ding, Investigation of the Thermomechanical Properties of a Plasma-Sprayed Nanostructured Zirconia Coating, J. Eur. Ceram. Soc., 2003, 23, p 1449-1455K.A. Khor and Y.W. Gu, Thermal Properties of Plasma-Sprayed Graded Thermal Barrier Coatings, Thin Solid Films, 2000, 372, p 104-113A.M. Limarga, T.S. Widjajab, and T.H. Yip, Mechanical Properties and Oxidation Resistance of Plasma-Sprayed Multilayered Al2O3/ZrO2 Thermal Barrier Coatings, Surf. Coat. Technol., 2005, 197, p 93-102X. Chen, Y. Zhao, X. Fan, Y. Liu, B. Zou, Y. Wang, H. Ma, and X. Cao, Thermal Cycling Failure of New LaMgAl11O19/YSZ Double Ceramic Top Coat Thermal Barrier Coating Systems, Surf. Coat. Technol., 2011, 205, p 3293-3300G. Mauer, M.O. Jarligo, D.E. Mack, and R. Vassen, Plasma-Sprayed Thermal Barrier Coatings: New Materials, Processing Issues and Solutions, J. Therm. Spray Technol., 2013, 22(5), p 647-658A. Portinha, V. Teixeira, J. Carneiro, J. Martins, M.F. Costa, R. Vassen, and D. Stoever, Characterization of Thermal Barrier Coatings with a Gradient in Porosity, Surf. Coat. Technol., 2005, 195, p 245-251M. Vicent, E. Sánchez, G. Mallol, and R. Moreno, Study of Colloidal Behaviour and Rheology of Al2O3-TiO2 Nanosuspensions to Obtain Free-Flowing Spray-Dried Granules for Atmospheric Plasma Spraying, Ceram. Int., 2013, 39(7), p 8103-8111F. Müller, W. Peukert, R. Polke, and R. Stenger, Dispersing Nanoparticles in Liquids, Int. J. Miner. Process., 2000, 74, p S31-S34M. Vicent, E. Bannier, R. Moreno, M.D. Salvador, and E. Sánchez, Atmospheric Plasma Spraying Coatings from Alumina-Titania Feedstock Comprising Bimodal Particle Size Distributions, J. Eur. Ceram. Soc., 2013, 33, p 3313-3324C.W. Kang and H.W. Ng, Splat Morphology and Spreading Behaviour due to Oblique Impact of Droplets onto Substrates in Plasma Spray Coating Process, Surf. Coat. Technol., 2006, 200, p 5462-5477Y. Zeng, S.W. Lee, L. Gao, and C.X. Ding, Atmospheric Plasma Sprayed Coatings of Nanostructured Zirconia, J. Eur. Ceram. Soc., 2002, 22, p 347-351R.S. Lima, A. Kucuk, and C.C. Berndt, Integrity of Nanostructured Partially Stabilized Zirconia After Plasma Spray Processing, Mater. Sci. Eng. A, 2001, 13, p 75-82L. Wang, Y. Wang, X.G. Sun, J.Q. He, Z.Y. Pan, and C.H. Wang, Microstructure and Indentation Mechanical Properties of Plasma Sprayed Nano-bimodal and Conventional ZrO2-8 wt%Y2O3 Thermal Barrier Coatings, Vacuum, 2012, 86(8), p 1174-1185L.L. Shaw, D. Goberman, R. Ren, M. Gell, S. Jiang, Y. Wang, T.D. Xiao, and P.R. Strutt, The Dependency of Microstructure and Properties of Nanostructured Coatings on Plasma Spray Conditions, Surf. Coat. Technol., 2000, 130(1), p 1-8R.S. Lima, A. Kucuk, and C.C. Berndt, Bimodal Distribution of Mechanical Properties on Plasma Sprayed Nanostructured Partially Stabilized Zirconia, J. Mater. Sci. Eng. A, 2002, 327, p 224-232T. Wakui, J. Malzbender, and R.W. Steinbrech, Strain Dependent Stiffness of Plasma Sprayed Thermal Barrier Coatings, Surf. Coat. Technol., 2006, 200(16-17), p 4995-5002J. Malzbender and R.W. Steinbrech, Determination of the Stress-Dependent Stiffness of Plasma-Sprayed Thermal Barrier Coatings Using Depth-Sensitive Indentation, J. Mater. Res., 2003, 18(8), p 1975-198
Mechanical properties and microstructural evolution of alumina-zirconia nanocomposites by microwave sintering
Microwave sintering has emerged in recent years as a novel method for sintering a variety of materials that have shown significant advantages
against conventional sintering procedures. This work involved an investigation of microwave hybrid fast firing of alumina–zirconia
nanocomposites using commercial alumina powder and monoclinic nanometric zirconia. The suspensions were prepared separately in order
to obtain 5, 10 and 15 vol% of ZrO2 in the alumina matrix. The samples were sintered in a monomode microwave furnace at 2.45 GHz in air at
different temperatures in the range 1200–1400 1C with 10 min of dwelling time and 200 1C/min of heating rate. The effect of sintering
temperature in densification, mechanical properties and microstructure behavior of the composites was investigated.
Higher density, hardness and Young's modulus, excellent fracture toughness properties and homogeneous microstructure were achieved by
microwave sintering in comparison to conventional heating. Microstructure analysis showed that the alumina grains had not grown significantly,
indicating that the zirconia particles provided a hindering effect on the grain growth of alumina.
Crown Copyright & 2014 Published by Elsevier Ltd and Techna Group S.r.l. All rights reservedThe authors would like to thank the Polytechnic University of Valencia (UPV) for financial support received for projects SP20120621, SP20120398 and SP20120677 and Spanish Government (TEC2012-37532-C02-01) and co-funded by ERDF (European Regional Development Funds). A. Borrell acknowledges the Spanish Ministry of Science and Innovation for her Juan de la Cierva contract (JCI-2011-10498) and Generalitat Valenciana by Geronimo Forteza funding (FPA/2012/022).Benavente Martínez, R.; Salvador Moya, MD.; Penaranda-Foix, FL.; Pallone, E.; Borrell Tomás, MA. (2014). Mechanical properties and microstructural evolution of alumina-zirconia nanocomposites by microwave sintering. Ceramics International. 40(7, Part B):11291-11297. https://doi.org/10.1016/j.ceramint.2014.03.153S1129111297407, Part
Design and use of an evaluation tool for assessment of instrumental skills within a subject related to materials science
[Otros] The interest in a competence-based approach in the university, continues increasing at a considerable rate in the European Higher Education Area. Generic competences (specific of the sort of education) assessment is nowadays considered crucial to support socio-educational demands. Nevertheless, the methodologies for the assessment/evaluation of the generic competences and their inclusion in the curriculum has yet to be adequately achieved. Competency-based learning requires either the development of new evaluation tools or adjustment of the existing ones in order to support marking changes needed for new learning-oriented active methodologies. In this sense, questionnaires are an innovative educational tool for competence evaluation although the development of a solid body of knowledge is still a pending task.
For this reason, this study proposes a methodological tool based on a questionnaire for rating the assessment (or not) of Specific Instrumental generic competence (instrumental skills), as defined in our university, by undergraduate students. In this regard, a practical intervention was designed to integrate the evaluation of activities related to Instrumental Skills in undergraduate students of Chemical Engineering, taking advantage of a computer practice session programmed as a part of the Materials Science subject. The appropriateness of the developed questionnaire, based on some learning outcomes, as a tool to properly score the competence of interest has been analysed by comparison of the obtained marks with the ones coming from more regular evaluation tools. The results may lead to some interesting conclusions to university professors when creating appropriate competency-based scoring questionnaires.Authors gratefully acknowledge the financial support of the Vicerrectorado de Estudios, Calidad y
Acreditación and the Vicerrectorado de Recursos Digitales y Documentación of the Universitat
Politècnica de València (Project PIME B/19-20/165 and Project PIME C/20-21/201) and the Instituto de
Ciencias de la Educación of the Universitat Politècnica de València (EICE INTEGRAL).Andrés-Ruiz, VT.; Sonseca Olalla, A.; Sahuquillo, O.; Benavente Martínez, R. (2021). Design and use of an evaluation tool for assessment of instrumental skills within a subject related to materials science. IATED Academy. 3964-3970. https://doi.org/10.21125/edulearn.2021.0837S3964397
High thermal stability of microwave sintered low-er beta-eucryptite materials
Low-temperature sinterable microwave LiAlSiO4-based solid-state material was investigated with regard to microwave dielectric properties as functions of the sintering temperature. beta-eucryptite materials and alumina-reinforced beta-eucryptite composites were sintered by microwave technology at 1100 degrees C and 1200 degrees C. The combination of fast heating and the dramatic reduction in cycle time, along with the non-conventional heating source, opens the way to produce materials with desired multifunctional properties.
The microstructure and crystalline composition of the materials were characterised, and the mechanical, thermal and microwave dielectric behaviours were analysed. X-ray diffraction showed good chemical stability in materials without between-phase reactions during the microwave sintering process. The excellent mechanical (similar to 8 GPa of hardness and similar to 100 GPa of Young's modulus), thermal (-0.23. 10(-6) K-1) and microwave dielectric properties (epsilon(r)= 4.10; Q=1494) were obtained from the LAS/Al2O3 composites sintered at a very low temperature (1100 degrees C). The results achieved show the possibility of designing ceramic nanocomposites at low sintering temperatures using microwave technology with near-zero thermal expansion coefficients, high mechanical and chemical stability and low dielectric properties.This work has been developed by different funded projects. The authors would like to thank their financial support: Project SP20120677 funded by the Polytechnic University of Valencia (UPV), Project TEC2012-37532-C02-01 (DINAWAVE) funded from Ministerio de Economia y Competitividad (MINECO) - Spanish government- and co-funded by ERDF (European Regional Development Funds) of European Union. Author A. Borrell, acknowledges the Spanish Ministry of Science and Innovation for her Juan de la Cierva contract (JCI-2011-10498).Benavente Martínez, R.; Salvador Moya, MD.; Penaranda-Foix, FL.; García-Moreno, O.; Borrell Tomás, MA. (2015). High thermal stability of microwave sintered low-er beta-eucryptite materials. Ceramics International. 41(10):13817-13822. https://doi.org/10.1016/j.ceramint.2015.08.066S1381713822411
Impact of Feedstock Nature on Thermal Conductivity of YSZ Thermal Barrier Coatings Obtained by Plasma Spraying
[EN] Yttria-stabilized zirconia (YSZ) coatings with low thermal conductivity were obtained using three different particle size distributions as starting powder: nano-, submicron- and bimodal submicron/nano-sized particles. On the one hand, these particles were reconstituted into micrometric, spray-dry agglomerates, which were subsequently deposited by means of conventional atmospheric plasma spraying (APS). On the other hand, the starting particles were dispersed in water and the resultant suspensions were deposited by means of suspension plasma spraying (SPS). The coatings were thermally treated to assess their sintering resistance. As-sprayed and thermally treated coatings were then characterized in terms of microstructure (FEG-SEM) and thermal diffusivity (laser flash equipment).
The results showed that SPS coatings exhibited extremely low thermal conductivity at low temperature which drastically augmented with increasing temperature. On the other hand, APS coatings also exhibited low thermal conductivities but their values were higher than those of the SPS coatings at the lowest temperature tested while the conductivities hardly varied with temperature.This work has been supported by the Spanish Ministry of Economy and Competitiveness (project MAT2015-67586-C3-R) and Research Promotion Plan of the Universitat Jaume I, action 2.1 (ref. E-2011 - 05) and action 3.1 (ref. PREDOC/2009/10). A. Borrell acknowledges the Spanish Ministry of Economy and Competitiveness for her Juan de la Cierva-Incorporacion contract (IJCI-2014-19839). M. Miranda would like to thank the European Commission (FP7-Marie Curie Intra-European Fellowship, BIOHYMAT).Carpio-Cobo, P.; Salvador Moya, MD.; Benavente Martínez, R.; Miranda, M.; Borrell Tomás, MA.; Sánchez, E. (2016). Impact of Feedstock Nature on Thermal Conductivity of YSZ Thermal Barrier Coatings Obtained by Plasma Spraying. Journal of Ceramic Science and Technology. 7(3):307-312. https://doi.org/10.4416/JCST2016-00022S3073127
Effect of the initial particle size distribution on the properties of suspension plasma sprayed Al2O3-TiO2 coatings
“NOTICE: this is the author’s version of a work that was accepted for publication in Surface & Coatings Technology. Changes resulting from the publishing process, such as peer review, editing, corrections, structural formatting, and other quality control mechanisms may not be reflected in this document. Changes may have been made to this work since it was submitted for publication. A definitive version was subsequently published in Surface & Coatings Technology, [268 (2015) 209-215] DOI 10.1016/j.surfcoat.2014.12.010¨Al2O3-TiO2 coatings have been deposited by atmospheric plasma spraying from agglomerated, nanostructured powders showing better properties than those of their conventional (microstructured) counterparts. These nanostructured coatings can be also obtained by suspension plasma spraying however the research on suspension plasma sprayed Al2O3-TiO2 is still scarce. Consequently, it is crucial to study the effect of the suspension characteristics on the coating properties and to optimize the deposition process.
In this work, Al2O3-13 wt.% TiO2 tribological coatings were successfully deposited by suspension plasma spraying from three different feedstocks: a nanometric suspension and two bimodal suspensions with different solid contents made up of titania nanoparticles and alumina submicron-sized particles. The coating microstructure and phase composition were characterized using scanning electron microscopy and X-ray diffraction analysis. Moreover, nanoindentation technique was used to determine the nanomechanical properties of coatings.
The influence of the feed suspension characteristics on the final coating quality was analyzed. Findings showed that similar microstructures and phases were developed after depositing the different feedstocks. In addition suspension feedstock made up of nanoparticles resulted in a coating with better mechanical properties. However the use of submicron-sized particles in the suspension feedstocks gives rise to some technical and economic advantages in the process which should be taken into account when a suspension plasma spraying process is to be setup. (C) 2014 Elsevier B.V. All rights reserved.This work has been supported by the Spanish Ministry of Science and Innovation (project MAT2012-38364-C03) and it has been co-funded by ERDF (European Regional Development Funds).Vicent, M.; Bannier, E.; Carpio, P.; Rayón Encinas, E.; Benavente Martínez, R.; Salvador Moya, MD.; Sánchez, E. (2015). Effect of the initial particle size distribution on the properties of suspension plasma sprayed Al2O3-TiO2 coatings. Surface and Coatings Technology. 268:209-215. https://doi.org/10.1016/j.surfcoat.2014.12.010S20921526