{"id":16,"date":"2024-05-31T10:21:14","date_gmt":"2024-05-31T08:21:14","guid":{"rendered":"https:\/\/wp.icmm.csic.es\/mscg\/?page_id=16"},"modified":"2024-09-05T13:42:55","modified_gmt":"2024-09-05T11:42:55","slug":"mechpropreliability","status":"publish","type":"page","link":"https:\/\/wp.icmm.csic.es\/mscg\/mechpropreliability\/","title":{"rendered":"Mechanical Properties and Structural Reliability"},"content":{"rendered":"

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Description<\/span><\/strong><\/a><\/b><\/p>\n<\/td>\n

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Experimental<\/span> techniques<\/span><\/strong><\/a><\/b><\/span><\/p>\n<\/td>\n

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Publications<\/a><\/strong><\/span><\/p>\n<\/td>\n

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Ph.D. Thesis<\/span><\/a><\/b><\/p>\n<\/td>\n

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Projects<\/span><\/a><\/b><\/p>\n<\/td>\n<\/tr>\n<\/tbody>\n<\/table>\n

MECHANICAL PROPERTIES AND STRUCTURAL RELIABILITY<\/p>\n

The group specialises in the mechanical behaviour, reliability and the relationship between microstructure and in-service behaviour of a wide range of advanced materials. For example, it studies the biomechanical behaviour of different commercial structural prostheses in order to replace the materials from which they are made with new materials that are more reliable, durable and at the same time multifunctional. This last research line is based on the basic knowledge acquired in the field of biomaterials to transfer it to a real clinical problem.<\/p>\n

The research lines currently focus on the study of:<\/p>\n

– Ceramic materials, composites and ceramic matrix nanocomposites.
\nThe scientific objective is the development of ceramic materials with high reproducibility and mechanical reliability. In this sense, research focuses on the study of different monolithic materials such as eco-piezoceramics subjected to an electric field or ceramics with dual microstructures, which are two-phase materials in which their components have different properties such as the coefficient of thermal expansion or the elastic modulus, or dissimilar composite materials such as ceramic-metal composites. This anisotropy in their properties and\/or composition can be used to produce an increase in toughness by means of shielding mechanisms that make these types of materials tolerant to defects. Likewise, laminated structures of both the ABAB type and with gradient function are being developed. In this type of macrostructures, an optimal stress distribution can be obtained in order to increase their structural reliability. In all these cases, a vitally important aspect is the study of their cyclic fatigue, i.e. under subcritical conditions, since it is under these conditions that the components formed by these types of materials are generally going to work.<\/p>\n

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– Materials and components for dental implantoprostheses
\nNowadays, the problems related to dental implants, in which this line of research is included, have an extraordinary impact both from a social point of view (in the EU alone the number of people who need implants is more than 100 million) and from an economic point of view. It is a sector with a spectacular growth (>20% per year), reaching a volume of \u20ac 5000 million in the EU alone. The results of this line have led to the development of a new generation of biomaterials for use in dental applications with a higher success rate than current implants. This is due to a lower number of clinical failures both biological, mainly associated with the reduction of the accumulation of dento-bacterial plaque that causes infections and\/or peri-implantitis (20% of the population is prone to this disease), and biomechanical, as these new materials with improved mechanical properties can withstand higher levels of load applied to the implant. To this end, we have worked with dentists, mainly from the UCM, and with different leading companies in the dental sector (Straumann, Zimmer, etc…) to evaluate commercial implants and their possible improvements.<\/p>\n

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– Biomechanics of vertebral prostheses
\nThis line of research is being focused in the field of cervical and spinal implantology, in collaboration with hospitals (e.g. Hospital Cl\u00ednico Universitario de Valencia, Hospital de Villalba de Madrid, etc.) and companies (e.g. Spineart). Biomechanical studies of the implants are carried out, which, together with clinical studies, show the critical dependence of the clinical success of this type of implants on the materials of which they are made. The ultimate aim of all this research is to replace the current materials used in prosthetic components that present major durability problems (breakage or wear), infections or diagnostic problems (artefacts generated using the NMR technique) with new materials developed in this line of research.<\/p>\n

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<\/a>Experimental techniques<\/span><\/strong><\/span><\/p>\n

Mechanical Characterisation Equipment<\/p>\n

– Universal testing machine SHIMADZU AG-X 5KN MS for static and quasi-static tests.
\n– SHIMADZU EMT-1KNV dynamic testing machine for cyclic testing at frequencies up to 100 Hz.
\n– MICROTEST Tribometer, model MT\/60\/NI (temperatures up to 150 \u00baC and tests in liquids).<\/p>\n

– LECO\u00a0 V-100-A2 Hardness tester.<\/p>\n

– BUEHLER MICROMET 5103 microindentation tester.<\/p>\n

– CSM instruments nano-hardness tester.<\/p>\n

<\/a>Publications<\/span><\/strong><\/span><\/p>\n

Publications (last 10 years)<\/p>\n

– ALONSO-PEREZ, R.; BARTOLOME, J. F.; PRADIES, G.
\n\u201cOriginal vs compatible stock abutment- implant connection: An in vitro analysis of the internal accuracy and mechanical fatigue behaviour\u201d<\/a><\/b>.Journal of Prosthodontic Research<\/em>, 66, 3, 476-483 (2022) DOI10.2186\/jpr.JPR_D_20_00066<\/p>\n

– GINER S., BARTOLOM\u00c9 J. F., GOMEZ-COGOLLUDO P., CASTELLOTE C., PRAD\u00cdES G.
\n\u201cFatigue fracture resistance of titanium and chairside CAD-CAM zirconia implant abutments supporting zirconia crowns: An in vitro comparative and finite element analysis study\u201d<\/a><\/b>.Journal of Prosthetic Dentistry<\/em>, 125, 3, 503.e1-503.e9 (2021) DOI10.1016\/j.prosdent.2020.09.025<\/p>\n

– ALONSO-P\u00c9REZ, R., BARTOLOM\u00c9, J.F., FRAILE, C., PRAD\u00cdES, G.
\n\u201cOriginal versus nonoriginal cast-to gold abutment-implant connection: Analysis of the internal fit and long-term fatigue performance\u201d<\/a><\/b>.Journal of Prosthetic Dentistry<\/em>, 126 (1), 94.e1-94.e9 (2021) DOI10.1016\/j.prosdent.2021.03.020<\/p>\n

– BARTOLOM\u00c9, J.F., FUENTES-COBAS, L.E., GARC\u00cdA, A., JACAS, A., PARDO, L.
\n\u201cCyclic mechanical fatigue lifetime of Bi0.5Na0.5TiO0.5-based eco-piezoceramics\u201d<\/a><\/b>.Materials<\/em>, 14(15), 4113 (2021). DOI10.3390\/ma14154113<\/p>\n

– GINER S., BARTOLOM\u00c9 J. F., GOMEZ-COGOLLUDO P., CASTELLOTE C., PRAD\u00cdES G.
\n\u201cMechanical Performance of Chairside Ceramic CAD\/CAM Restorations and Zirconia Abutments with Different Internal Implant Connections: In Vitro Study and Finite Element Analysis\u201d<\/a><\/b>.Materials<\/em>, 14 (7) 5009 (2021). DOI10.3390\/ma14175009<\/p>\n

– RODRIGO-V\u00c1ZQUEZ, C.S., BARTOLOM\u00c9, J.F., RODR\u00cdGUEZ, M.A., DE AZA, A.H.
\n\u201cMicrostructural development and mechanical performance of CaSiO3\u2013Ca3(PO4)2 bioceramics following the addition of CaSiO3\u2013Ca3(PO4)2\u2013MgCa(SiO3)2 eutectic glass\u201d<\/a><\/b>.Ceramics International<\/em> 47, 4, 5502-5509 (2021).<\/p>\n

– DEL PI\u00d1AL, M., LOPEZ-SUAREZ, C., BARTOLOME, J.F., VOLPATO, C.A.,SUAREZ, M.J.
\n\u201cEffect of cementation and aging on the marginal fit of veneered and monolithic zirconia and metal-ceramic CAD-CAM crowns\u201d<\/a><\/b>. Journal of Prosthetic Dentistry<\/em>, 125, 2, (2021) DOI10.1016\/j.prosdent.2020.06.036<\/p>\n

– CLEMENS KUNZ; J\u00d6RN BONSE; DIRK SPALTMANN; CHRISTOF NEUMANN; ANDREY TURCHANIN; JOS\u00c9 F BARTOLOM\u00c9; FRANK A M\u00dcLLER; STEPHAN GRAEF.
\n\u201cTribological performance of metal-reinforced ceramic composites selectively structured with femtosecond laser-induced periodic surface structures\u201d<\/a><\/b>. Applied Surface Science<\/em>, 499,143917 (2020). DOI10.1016\/j.apsusc.2019.143917<\/p>\n

– ARAUJO, MS., SILVA, AC., BARTOLOME, JF., MELLO-CASTANHO, S.
\n\u201cStructural and thermal behavior of 45S5 Bioglass\u00ae-based compositions containing alumina and strontium\u201d <\/a><\/b>. Journal of the American Ceramic Society<\/em>, 103(6) 3620-3630 (2020).<\/p>\n

– D\u00cdAZ M., SMIRNOV, A., GUTI\u00c9RREZ-GONZ\u00c1LEZ C.F., ESTRADA D., BARTOLOM\u00c9, J.F.
\n\u201cMicrostructure and Mechanical Properties of Zirconia (3Y-TZP)\/Zr Composites Prepared by Wet Processing and Subsequent Spark Plasma Sintering\u201d<\/a><\/b>. Ceramics<\/em>, 3(1), 53-64 (2020). DOI10.3390\/ceramics3010007<\/p>\n

– ARAUJO, MS., BARTOLOME, JF., MELLO-CASTANHO, S.
\n\u201cTribological and mechanical behaviour of 45S5 Bioglass\u00ae-based compositions containing alumina and strontium\u201d<\/a><\/b>. Ceramics International<\/em>, 46, 15, 24347-24354 (2020). DOI10.1016\/j.ceramint.2020.06.216<\/p>\n

– SMIRNOV, A., PERETYAGIN, P. PINARGOTE, N.W.S., GERSHMAN, I., BARTOLOM\u00c9, J.F.
\n\u201cWear behavior of graphene-reinforced Alumina\u2013Silicon carbide Whisker nanocomposite\u201d<\/a><\/b>. Nanomaterials<\/em> Vol. 9, N2, Article number 151 (2019). DOI10.3390\/nano9020151<\/p>\n

– L\u00d3PEZ-P\u00cdRIZ, R., CABAL, B., GOYOS-BALL, L., FERN\u00c1NDEZ, A., BARTOLOM\u00c9, J.F., MOYA, J.S., TORRECILLAS, R.
\n\u201cCurrent state-of-the-art and future perspectives of the three main modern implant-dentistry concerns: Aesthetic requirements, mechanical properties, and peri-implantitis prevention\u201d<\/a><\/b>. Journal of Biomedical Materials Research – Part A<\/em> 107A:1466\u20131475 (2019). DOI10.1002\/jbm.a.36661<\/p>\n

– P\u00c9REZ LE\u00d3N, P., BARTOLOM\u00c9, J.F., LOMBARD\u00cdA, C., PRAD\u00cdES, G.
\n\u201cMechanical fatigue behaviour of different lengths screw-retained restorations connected to two designs prosthetic connection level\u201d<\/a><\/b>. Journal of Oral Rehabilitation<\/em> 46,(8), 747-755 (2019). DOI10.1111\/joor.12809<\/p>\n

– SMIRNOV, A., PERETYAGIN, P. , BARTOLOM\u00c9, J.F.
\n\u201cProcessing and mechanical properties of new hierarchical metal-graphene flakes reinforced ceramic matrix composites\u201d<\/a><\/b>. Journal of the European Ceramic Society<\/em> 39 (12) 3491-3497 (2019). DOI10.1016\/j.jeurceramsoc.2019.02.044<\/p>\n

– SMIRNOV, A., SELEZNEV, A., PINARGOTE, N.W.S., PRISTINSKIY, Y., PERETYAGIN, P., BARTOLOM\u00c9, J.F.
\n\u201cThe influence of wire electrical discharge machining cutting parameters on the surface roughness and flexural strength of ZrO2\/TiN ceramic nanocomposites obtained by spark plasma sintering\u201d<\/a><\/b>. Nanomaterials<\/em> Vol. 9, N10, Article number 1391 (2019). DOI10.3390\/nano9101391<\/p>\n

– SMIRNOV, A; VOLOSOVA, M.; PERETJAGIN, P; BARTOLOM\u00c9, JF.
\n\u201cTribological behaviour of a 3Y-TZP\/Ta ceramic-metal biocomposite against ultrahigh molecular weight polyethylene (UHMWPE)\u201d<\/a><\/b>. Ceramics International<\/em> 44(2), 1404-1410 (2018) DOI10.1016\/j.ceramint.2017.09.186<\/p>\n

– A. JORGE-MORA, N. IMAZ, N. FRUTOS, A. ALONSO, C. GARC\u00cdA SANTIAGO, R. G\u00d3MEZ-VAAMONDE, J. PINO-MINGUEZ, J. F. BARTOLOM\u00c9, G. O\u2019CONNOR AND D. NIETO.
\n\u201cIn Vitro Evaluation of Laser-Induced Periodic Surface Structures on New Zirconia\/Tantalum Biocermet for Hard-Tissue Replacement\u201d<\/b>. Laser Ablation – From Fundamentals to Applications<\/em> ISBN: 978-953-51-3700-9 (2018)<\/p>\n

– SMIRNOV A., PERETJAGIN, P; BARTOLOM\u00c9, JF.
\n\u201cWire electrical discharge machining of 3Y-TZP\/Ta ceramic-metal composites)\u201d<\/a><\/b>. Journal of Alloys and Compounds<\/em> 739, 62-68 (2018). DOI10.1016\/j.jallcom.2017.12.221<\/p>\n

– ALONSO-P\u00c9REZ, R., BARTOLOM\u00c9, J.F., FERREIROA, A., SALIDO, M.P., PRAD\u00cdES, G.
\n\u201cOriginal vs. non-original abutments for screw-retained single implant crowns: An in vitro evaluation of internal fit, mechanical behaviour and screw loosening\u201d<\/a><\/b>. Oral Implants Research<\/em> Vol. 29, N12, 1230-1238 (2018). DOI10.1111\/clr.13390<\/p>\n

– ALONSO-P\u00c9REZ, R., BARTOLOM\u00c9, J.F., FERREIROA, A., SALIDO, M.P., PRAD\u00cdES, G.
\n\u201cEvaluation of the mechanical behavior and marginal accuracy of stock and laser-Sintered implant abutments\u201d<\/a><\/b>. International Journal of Prosthodontics<\/em> Vol. 30, N 2, 136-138 (2017) DOI10.11607\/ijp.5089<\/p>\n

– SMIRNOV, A; BELTR\u00c1N, JI; RODRIGUEZ-SUAREZ, C; PECHARROM\u00c1N, C; MU\u00d1OZ, MC; MOYA, JS; BARTOLOM\u00c9, JF.
\n\u201cUnprecedented simultaneous enhancement in damage tolerance and fatigue resistance of zirconia\/Ta composites\u201d<\/a><\/b>. Scientific Reports<\/em> 7, Article number 4492 (2017) DOI10.1038\/srep44922<\/p>\n

– MOYA, JS; BARTOLOM\u00c9, JF.
\n\u201cTeam develops damage-tolerant, fatigue-resistant, and biocompatible ceramic\u2013metal composite\u201d<\/b>. American Ceramic Society Bulletin, 96 (5) 18 (2017)<\/p>\n

– A. SMIRNOV, J. F. BARTOLOM\u00c9, H-DIETER KURLAND, J. GRABOW, F. A. M\u00dcLLER.
\n\u201cDesign of a new zirconia-alumina-Ta micro-nanocomposite with unique mechanical properties\u201d<\/a><\/b>. Journal of the American Ceramic Society<\/em> 99 [10] 3205\u20133209 (2016)<\/p>\n

– C.F. GUTIERREZ-GONZALEZ, A. SMIRNOV, A. CENTENO, A. FERN\u00c1NDEZ, B. ALONSO, V.G. ROCHA, R. TORRECILLAS, A. ZURUTUZA and J.F. BARTOLOME.
\n\u201cWear behavior of graphene\/alumina composite\u201d<\/a><\/b>. Ceramics International<\/em> 41, 7434-7438 (2015)<\/p>\n

– A. SMIRNOV, H-DIETER KURLAND, J. GRABOW, F. A. M\u00dcLLER, and J. F. BARTOLOM\u00c9.
\n\u201cMicrostructure, mechanical properties and low temperature degradation resistance of 2Y-TZP ceramic materials derived from nanopowders prepared by laser vaporization\u201d<\/a><\/b>. Journal of European Ceramic Society<\/em> 35, 2685-2691 (2015)<\/p>\n

– A. CASCALES, N. TABARES, J. F. BARTOLOM\u00c9, A. CERPA, A. SMIRNOV, R. MORENO and M. I. NIETO.
\n\u201cProcessing and mechanical properties of mullite and mullite-alumina composites reinforced with carbon nanofibers\u201d<\/a><\/b>. Journal of European Ceramic Society<\/em> 35, 3613-3621 (2015)<\/p>\n

– J. F. BARTOLOM\u00c9, A. SMIRNOV, F. SOMMER, F. LANDFRIED and R. GADOW.
\n\u201cSliding Wear Behavior of ZTA with Different Yttria Stabilizer Content\u201d<\/a><\/b>. Journal of the American Ceramic Society<\/em>98, 12, 3981-3987 (2015)<\/p>\n

– GUTIERREZ-GONZALEZ C.F., SOLIS PINARGOTE N.W., AGOURAM S., PERETYAGIN P.Y., LOPEZ-ESTEBAN S., TORRECILLAS R.
\n\u201cSpark plasma sintering of zirconia\/nano-nickel composites\u201d<\/a><\/b>. Mechanics and Industry<\/em> 16 7 (2015). DOI: 10.1051\/meca\/2015090<\/p>\n

– FERNANDEZ-GARCIA E., GUTIERREZ-GONZALEZ C.F., PERETYAGIN P., SOLIS W., LOPEZ-ESTEBAN S., TORRECILLAS R., FERNANDEZ A.
\n\u201cEffect of yttria-titanium shell-core structured powder on strength and ageing of zirconia\/titanium composites\u201d<\/a><\/b>. Materials Science and Engineering A<\/em>. , 646, Art. No. 32682 96-100 (2015). DOI: 10.1016\/j.msea.2015.08.048<\/p>\n

– A. SMIRNOV, and J. F. BARTOLOM\u00c9.
\n\u201cMicrostructure and mechanical properties of ZrO2 ceramics toughened by 5-20 vol.% Ta metallic particles fabricated by pressureless sintering\u201d<\/a><\/b>. Ceramics International<\/em> 40, 1B, 1829-184 (2014)<\/p>\n

– S. LOPEZ-ESTEBAN, J.F.BARTOLOME, L.A.DIAZ, L.ESTEBAN-TEJEDA, C.PRADO,R. LOPEZ-PIRIZ, R.TORRECILLAS, and J.S.MOYA.
\n\u201cMechanical performance of a biocompatible biocide soda\u2013lime glass-ceramic\u201d<\/a><\/b>. Journal of the Mechanical Behavior of Biomedical Materials<\/em> 34, 302\u2013312 (2014).<\/p>\n

– C.F. GUTIERREZ-GONZALEZ, E. FERNANDEZ-GARCIA, A. FERNANDEZ, R. TORRECILLAS and S. LOPEZ-ESTEBAN.
\n\u00abProcessing, spark plasma sintering, and mechanical behavior of alumina\/titanium composites\u201d<\/a><\/b>. Journal of Materials Science<\/em>. 49 3823\u20133830 (2014). DOI: 10.1007\/s10853-014-8095-5<\/p>\n

<\/a>Ph.D. Thesis<\/span><\/strong><\/span><\/p>\n

Ph.D. thesis (last 10 years)<\/p>\n