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Publikációk Idézettsége (320) Gubicza Jenő publikációinak idézettsége (2107 db független hivatkozás) Citations to publications of Jeno Gubicza (number of independent citations: 2107) A. Juhász, M. Dimitrova-Lukács, G. Vörös, J. Gubicza, P. Tasnádi, P. Lukács and A. Kele: Continuous indentation on glasses and ceramics, Fortchrittsberichte der Deutschen Keramischen Gesellschaft, 9 (1994) 87-97. 1. E. Rudnayová, L. Pesek: A simple method for determining the Young's modulus of ceramics by indentation technique, Proc. of the International Conference on Deformation and Fracture in Structural PM Materials, edited by L. Parilák, H. Daminger, J. Dusza, B. Weiss, IMR-SAS Kosice, Vol.2., 1996, pp. 256-261. 2. E. Rudnayová, P. Hvizdos, P. Arató, L. Pesek: Young's modulus measurement of silicon nitride ceramics by indentation methods, Key Engineering Materials 175 (2000) 335-340. J. Gubicza: Characterization of glasses and ceramics by continuous indentation tests, Key Eng. Mater. 103 (1995) 217-220 1. G. Kaya: Production and Characterization of Self-Colored Dental Zirconia Blocks, Ceramics International 39 (2013) 511-517. J. Gubicza, A. Juhász, P. Tasnádi, P. Arató and G. Vörös: Determination of the hardness and elastic modulus from continuous Vickers indentation test, J. Mater. Sci. 31 (1996) 3109-3114. 1. A. Flores, F. J. B. Calleja and H. R. Kricheldorf: Mechanical study of sintered aromatic polyesters as revealed by microindentation measurements, J. Mater. Sci. 33, 14 (1998) 3567-3571. 2. C J Wu, T M Shao, A G Mu, W L Du, C Coddet: Plasma spray ceramic plunger for polymer pump, Proceedings of the International Thermal Spray Conference. 1998.05.25-1998.05.29, pp. 1043-1048. 3. J. Thurn, D. J. Morris and R.F. Cook: Depth-sensing indentation at macroscopic dimensions, J. Mater. Res. 17 (2002) 2679-2690. 4. N. Llorca-Isern, P. A. Gonzalez, C. J. Luis, I. Laborde: Severe Plastic Deformation of a commercial aluminium-lithium alloy (AA8090) by Equal Channel Angular Pressing, Mater. Sci. Forum 503-504 (2006) 871-876. 5. M. Abou Zied: Microstructure and mechanical properties of nano-crystalline Al-8 wt% Ni alloy, J. Mater. Sci. & Techn. 22 (2006) 605-610. 6. K. Kazmanli, B. Daryal and M. Urgen: Characterization of nano-composite TiN– Sb coating produced with hybrid physical vapor deposition system, Thin Solid Films 515 (2007) 3675-3680. 7. N. Ponce-Garcia, J.D.C. Figueroa, G.A. Lopez-Huape, H.E. Martinez, R. Martinez-Peniche: Study of viscoelastic properties of wheat kernels using compression load method, Cereal Chemistry 85 (2008) 667-672. 8. I.N. Orbulov, Á. Németh, J. Dobránszky: Compressive strength and hardness of metal matrix syntactic foams, Journal of Physics: Conference Series 240 (2010) art. no. 012168. 1 9. J.D.C. Figueroa, Z.J.E. Hernández, M.J.J. Véles, P.R. Duarte, H.E. Martínez- Flores, N. Ponce-García: Evaluation of degree of elasticity and other mechanical properties of wheat kernels, Cereal Chemistry 88 (2011) 12-18. 10. J.D.C. Figueroa, R.J. Pena, T. Maucher, P. Rayas-Duarte, K. Khan: Kernel elastic properties and sedimentation: Influence of high and low molecular weight glutenin allelic composition, Cereal Chemistry 88 (2011) 41-44. 11. J.D.C. Figueroa, R.J. Pena, P. Rayas-Duarte, K. Khan: Influence of Low-molecular Weight Glutenin Subunits on Wheat Kernel Elasticity and Sedimentation CEREAL RESEARCH COMMUNICATIONS 39 (2011) 237-245. 12. Z.J.E. Hernández, J.D.C. Figueroa, P Rayas-Duarte, H.E. Martínez-Flores, V.G. Arámbula, B.G. Luna, R.J. Pena: Influence of high and low molecular weight glutenins on stress relaxation of wheat kernels and the relation to sedimentation and rheological properties, Journal of Cereal Science 55 (2012) 344-350. 13. Lu, Y.: Analysis of large-strain microindentation of crystalline polymers, Book Editor(s): Davim, JP, Source: MATERIALS AND SURFACE ENGINEERING: RESEARCH AND DEVELOPMENT, Woodhead Publishing Reviews-Mechanical Engineering, Issue: 2, Pages: 61-95 (2012) 14. Ponce-García, N., Ramírez-Wong, B., Torres-Chávez, P.I., De Dios Figueroa- Cárdenas, J., Serna-Saldívar, S.O., Cortez-Rocha, M.O.: Effect of moisture content on the viscoelastic properties of individual wheat kernels evaluated by the uniaxial compression test under small strain, Cereal Chemistry 90 (2013) 558-563. J. Gubicza, A. Juhász and J. Lendvai: A new method for hardness determination from depth sensing indentation tests, J. Mater. Res. 11 (1996) 2964-2967. 1. S. P. Baker: Between nanoindentation and scanning force microscopy: measuring mechanical properties in the nanometer regime, Thin Solid Films, 308-309 (1997) 289-296. 2. C. Carney and D. Durham: Optimization of hardness by the control of microwave- power in TiN thin film deposited by electron-cyclotron-resonance assisted sputtering in a nitrogen plasma, Journal of Vacuum and Technology A- Vacuum, Surfaces and Films, 17, 5 (1999) 2535-2541. 3. C. Carney and D. Durham: Establishing the reletionship between process, structure and properties of thin films deposited by electron-cyclotron-resonance assisted reactive sputtering- I- Variations in hardness and roughness as a function of process parameters, Journal of Vacuum and Technology A- Vacuum, Surfaces and Films, 17, 5 (1999) 2850-2858. 4. K. Tunvisut, N. P. O’Dowd and E. P. Busso: Use of scaling functions to determine mechanical properties of thin coatings from microindentation tests, Int. Journal of Solids and Structures, 38 (2001) 335-351. 5. V. Bursikova, V. Navratil, L. Zajickova and J. Janca: Temperature dependence of mechanical properties of DLC/Si protective coatings prepared by PECVD, Mater. Sci. Eng. A 324 (2002) 251-254. 6. P. Nagy, A. Csanády, B. Verő, G. Pálinkás and E. Kálmán: The combined application of nanoindentation and scanning probe microscopy to materials sciences, Mater. Sci. Forum, 414-415 (2003) 297-303. 7. D. J. Ma, C. W. Ong, J. Lu and J. W. He: Methodology for the evaluation of yield strength and hardening behavior of metallic materials by indentation with spherical tip, J. Appl. Phys. 94 (2003) 288-294. 2 8. M. Verdier: AFM, TEM and nanoindentation characterizations of plastic deformation in metallic multilayers, Revue de Metallurgie-Cahiers d'Informations Techniques 100 (2003) 535-540. 9. B. Wolf, A. Richter, V. Weihnacht: Differential and integral hardness - new aspects of quantifying load-depth-data in depth-sensing nanoindentation experiments, Surface and Coatings Technology 183 (2004) 141-150. 10. Ch.-H. Kim, A. H. Heuer: A high-temperature displacement-sensitive indenter for studying mechanical properties of thermal barrier coatings, J. Mater. Res. 19 (2004) 351-356. 11. Y.-T. Cheng, C.-M. Cheng: Scaling, dimensional analysis, and indentation measurements, Mater. Sci. Eng. R 44 (2004) 91-149. 12. P.M. Nagy, P. Horvath, E. Kalman, F. Kormos: Mechanical relaxation of Sn-2 protective layers evaluated by nanoindentation and AFM, Mater. Manufacturing Processes 20 (2005) 115-122. 13. N. Laidani, R. Bartali, M. Anderle, P. Chiggiato, G. Chuste: Carbon film deposition on polyethylene terephtalate by pulsed-plasma technology, Diamond and Related Materials 14 (2005) 1023-1030. 14. P.M. Nagy, P. Horváth, D. Aranyi, E. Kálmán: Relaxation issues in nanoindentation experiments, Current Applied Physics 6 (2006) 154-160. 15. M. Martyniuk, J.Antoszewski, B.A.Walmsley, C.A.Musca, J.M. Dell, Y.-G. Jung, B.R. Lawn, H. Huang, L. Faraone: Determination of mechanical properties of silicon nitride thin films using nanoindentation, Proceedings of SPIE - The International Society for Optical Engineering, 5798 (2005) 216-225. 16. M. Martyniuk, R.H. Sewell, C.A. Musca, J.M. Dell, L. Faraone: Determination of HgCdTe elasto-plastic properties using nanoindentation, Journal of Electronic Materials, 35 (2006) 1197-1205. 17. R. Bartali, V. Micheli, G. Gottardi, A. Vaccari, N. Laidani: Nanoindentation: Unload-to-load work ratio analysis in amorphous carbon films for mechanical properties, Surface and Coatings Technology, 204 (2010) 2073-2076. 18. M. Antonov, I. Hussainova: Cermets surface transformation under erosive and abrasive wear, Tribology International, 43 (2010) 1566-1575. 19. J. Chen, H.N. Chen, J. Chen: Evaluation of mechanical properties of structural materials by a spherical indentation based on the representative strain-an improved algorithm at great depth ratio, ACTA METALLURGICA SINICA (ENGLISH LETTERS) 24 (2011) 405-414. 20. D. Kawakami, K. Ohara, T. Takubo, Y. Mae, A. Ichikawa, T. Tanikawa, T. Arai: Cell hardness measurement by using two-fingered microhand with micro force sensor, Proc. IEEE International Conference on Intelligent Robots and Systems, San Francisco, USA, 25-30 September 2011, ISBN: 978-161284454-1, (2011) art. no. 6048411, pp. 25-30. 21. K. Ohara, D. Kawakami, T. Takubo, Y. Mae, T. Tanikawa, A. Honda, T. Arai: Dextrous cell diagnosis using two-fingered microhand with micro force sensor, J. Micro-Nano Mech. 7 (2012) 13-20. 22. J. Chen, H. Chen, J. Chen: Evaluation of mechanical properties of metal materials by spherical indentation based on representative strain - Characterizing of P-h curve at great depth ratio, Jixie Qiangdu/Journal of Mechanical Strength 34 (2012) 818-822. 23. M. Naderi, K. Sardashti, A. Sharbatian, M. Iranmanesh: An investigation into depth sensning of hardness maps by means of image processing techniques, Proc. 3 of 21st Conference on Measurement of Force, Mass and Torque Together with HARDMEKO 2010 and 2nd Meeting on Vibration Measurement, IMEKO TC3, TC5 and TC22 Conferences, 21-25 November 2010, Pattaya, Thailand, (2010) Pages 159-165. J. Gubicza, A. Juhász, P. Arató, P. Szommer, P. Tasnádi and G. Vörös: Elastic modulus determination from depth sensing indentation testing, J. Mater. Sci. Letters 15 (1996) 2141- 2144. 1. E. Rudnayová, L. Pesek: A simple method for determining the Young's modulus of ceramics by indentation technique, Proc. of the International Conference on Deformation and Fracture in Structural PM Materials, edited by L. Parilák, H. Daminger, J. Dusza, B. Weiss, IMR-SAS Kosice, Vol.2., 1996, pp. 256-261. 2. V. Bursikova, V. Navratil, L.
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