Investigation of modern ceramics in bioelectrical engineering with proper thermal and mechanical properties
محورهای موضوعی :
فصلنامه شبیه سازی و تحلیل تکنولوژی های نوین در مهندسی مکانیک
Sharif Heydari
1
(
Department of Biomedical Engineering, Kerman Branch, Islamic Azad University, Kerman, Iran
)
Ali Attaeyan
2
(
Department of Biomedical Engineering, Biomechanics Faculty, Najafabad Branch, Islamic Azad University, Najafabad, Iran
)
Pegah Bitaraf
3
(
Biomedical Engineering Department, Islamic Azad University Science and Research Branch, Tehran, Iran
)
Amir Mohammad Gholami
4
(
Department of Mechanical Engineering, Najafabad Branch, Islamic Azad University, Najafabad, Iran
)
Bahareh Kamyab Moghadas
5
(
Department of Applied Researches, Chemical, Petroleum & Polymer Engineering Research Center, Shiraz Branch, Islamic Azad University, Shiraz, Iran
)
تاریخ دریافت : 1400/09/28
تاریخ پذیرش : 1400/11/22
تاریخ انتشار : 1400/05/10
کلید واژه:
Ceramic engineering,
Electrical component,
Electro ceramics,
Mechanical performance,
چکیده مقاله :
Today, electronic ceramics make up the largest share of advanced markets. Ceramics are chemically neutral and resistant to high temperatures, so they provide a good environment for circuits. Most ceramics have electronic mobility. Ceramic engineering is one of the attractive trends in the field of materials science and engineering. In ceramic engineering, parts are made of inorganic and non-metallic materials. Like other trends in materials engineering, ceramic engineering is based on the study of the structure, chemical composition and properties of ceramic materials from the atomic dimension of the material to its bulk structure. Ceramic materials have different crystalline, semi-crystalline and amorphous structures. In other classifications, ceramics are divided into two categories such as traditional and advanced ceramics. Therefore, in this we evaluate the mechanical properties and application of the modern ceramics. Nowadays, the study of engineered and advanced ceramics is very widespread. Advanced ceramics are a group of ceramics that have components, complex manufacturing technology and more sensitive applications, and different categories are considered for them in which are in the form of engineering ceramics, glass ceramics, electro ceramics and bioceramics.
منابع و مأخذ:
Dalcanale, F., Grossenbacher, J., Blugan, G., Gullo, M. R., Lauria, A., Brugger, J. & Kuebler, J. (2014). Influence of carbon enrichment on electrical conductivity and processing of polycarbosilane derived ceramic for MEMS applications. Journal of the European Ceramic Society, 34(15), 3559-3570.
Otitoju, T. A., Okoye, P. U., Chen, G., Li, Y., Okoye, M. O., & Li, S. (2020). Advanced ceramic components: Materials, fabrication, and applications. Journal of industrial and engineering chemistry, 85, 34-65.
Wang, P., Cao, Q., Wang, H., Liu, S., Chen, Y., & Peng, Q. (2021). CNT-sandwiched copper composites as super thermal conductors for heat management. Physica E: Low-dimensional Systems and Nanostructures, 128, 114557.
Li, Y., Wei, P., & Ma, H. (2017). Integrated optimization of heat-transfer systems consisting of discrete thermal conductors and solid material. International Journal of Heat and Mass Transfer, 113, 1059-1069.
Danzer, R. (2014). On the relationship between ceramic strength and the requirements for mechanical design. Journal of the European Ceramic Society, 34(15), 3435-3460.
De, M., Ghosh, P. S., & Rotello, V. M. (2008). Applications of nanoparticles in biology. Advanced Materials, 20(22), 4225-4241.
Grondzik, Walter T.; Kwok, Alison G. Mechanical and electrical equipment for buildings. John wiley & sons, 2019.
Jadin, M. S., & Taib, S. (2012). Recent progress in diagnosing the reliability of electrical equipment by using infrared thermography. Infrared Physics & Technology, 55(4), 236-245.
Hong, Y., Li, J., Wu, W., Wu, Y., Bai, H., Shi, K., ... & Jia, D. (2018). Structure, electricity, and bandgap modulation in Fe2O3–doped potassium sodium niobate ceramics. Ceramics International, 44(13), 16069-16075.
Hasirci, V., & Hasirci, N. (2018). Fundamentals of biomaterials. Verlag: Springer New York.
Yan, T. P. (2013). Application Analysis of functional ceramics materials. In Applied Mechanics and Materials(Vol. 373, pp. 1975-1978). Trans Tech Publications Ltd.
Tangsen, Z. (2012). Study on missing data adjustment modified optimization smoothing algorithm and its application in ceramics. China Ceramics.
Wesolowski, R. A., Wesolowski, A. P., & Petrova, R. S. (2020). Introduction to Ceramics. In The World of Materials(pp. 69-74). Springer, Cham.
Pirmoradian, M., Naeeni, H. A., Firouzbakht, M., Toghraie, D., & Darabi, R. (2020). Finite element analysis and experimental evaluation on stress distribution and sensitivity of dental implants to assess optimum length and thread pitch. Computer methods and Programs in Biomedicine, 187, 105258.
Heydari, E., Mokhtarian, A., Pirmoradian, M., Hashemian, M., & Seifzadeh, A. (2020). Sound transmission loss of a porous heterogeneous cylindrical nanoshell employing nonlocal strain gradient and first-order shear deformation assumptions. Mechanics Based Design of Structures and Machines, 1-22.
Eslami, M., Mokhtarian, A., Pirmoradian, M., Seifzadeh, A., & Rafiaei, M. (2020). Design and fabrication of a passive upper limb rehabilitation robot with adjustable automatic balance based on variable mass of end-effector. Journal of the Brazilian Society of Mechanical Sciences and Engineering, 42(12), 1-8.
Eslami, M., Mokhtarian, A., Pirmoradian, M., Seifzadeh, S. A., & Rafiaei, S. M. (2020). Designing and creating a virtual reality environment and a wearable glove with control and evaluation capability to rehabilitate patients. Journal of Health and Biomedical Informatics, 7(2), 161-170.
Torkan, E., & Pirmoradian, M. (2019). Efficient higher-order shear deformation theories for instability analysis of plates carrying a mass moving on an elliptical path. Journal of Solid Mechanics, 11(4), 790-808.
Eslami, M., Pirmoradian, M., Mokhtarian, A., Seifzadeh, S. A., & Rafiaei, S. M. (2020). Investigating the Effect of Virtual Reality Environment and Intelligent Control Panel on the Rehabilitation of Upper Limb. Journal of Health and Biomedical Informatics, 7(3), 293-303.
Khandan, A., Abdellahi, M., Ozada, N., & Ghayour, H. (2016). Study of the bioactivity, wettability and hardness behaviour of the bovine hydroxyapatite-diopside bio-nanocomposite coating. Journal of the Taiwan Institute of Chemical Engineers, 60, 538-546.
Karamian, E., Motamedi, M. R. K., Khandan, A., Soltani, P., & Maghsoudi, S. (2014). An in vitro evaluation of novel NHA/zircon plasma coating on 316L stainless steel dental implant. Progress in Natural Science: Materials International, 24(2), 150-156.
Najafinezhad, A., Abdellahi, M., Ghayour, H., Soheily, A., Chami, A., & Khandan, A. (2017). A comparative study on the synthesis mechanism, bioactivity and mechanical properties of three silicate bioceramics. Materials Science and Engineering: C, 72, 259-267.
Ghayour, H., Abdellahi, M., Ozada, N., Jabbrzare, S., & Khandan, A. (2017). Hyperthermia application of zinc doped nickel ferrite nanoparticles. Journal of Physics and Chemistry of Solids, 111, 464-472.
Khandan, A., Jazayeri, H., Fahmy, M. D., & Razavi, M. (2017). Hydrogels: Types, structure, properties, and applications. Biomat Tiss Eng, 4(27), 143-69.
Khandan, A., Abdellahi, M., Ozada, N., & Ghayour, H. (2016). Study of the bioactivity, wettability and hardness behaviour of the bovine hydroxyapatite-diopside bio-nanocomposite coating. Journal of the Taiwan Institute of Chemical Engineers, 60, 538-546.
Khandan, A., Karamian, E., & Bonakdarchian, M. (2014). Mechanochemical synthesis evaluation of nanocrystalline bone-derived bioceramic powder using for bone tissue engineering. Dental Hypotheses, 5(4), 155.
Hamedani Morteza, P., Reza, F. M., Nasrin, S., Ehsan, N., Shams Ali, R., & Amini, M. (2007). Deterioration of parabens in preserved magnesium hydroxide oral suspensions. Journal of Applied Sciences, 7(21), 3322-3325.
Ghomi, F., Daliri, M., Godarzi, V., & Hemati, M. (2021). A novel investigation on characterization of bioactive glass cement and chitosan-gelatin membrane for jawbone tissue engineering. Journal of Nanoanalysis.
Mirsasaani, S. S., Hemati, M., Dehkord, E. S., Yazdi, G. T., & Poshtiri, D. A. (2019). Nanotechnology and nanobiomaterials in dentistry. In Nanobiomaterials in clinical dentistry(pp. 19-37). Elsevier.
Mirsasaani, S. S., Bahrami, M., & Hemati, M. (2016). Effect of Argon laser Power Density and Filler content on Physico-mechanical properties of Dental nanocomposites. Bull. Pharmacol. Life Sci, 5, 28-36.
Talebi, M., Abbasi‐Rad, S., Malekzadeh, M., Shahgholi, M., Ardakani, A. A., Foudeh, K., & Rad, H. S. (2021). Cortical bone mechanical assessment via free water relaxometry at 3 T. Journal of Magnetic Resonance Imaging, 54(6), 1744-1751.
Lucchini, R., Carnelli, D., Gastaldi, D., Shahgholi, M., Contro, R., & Vena, P. (2012). A damage model to simulate nanoindentation tests of lamellar bone at multiple penetration depth. In 6th European Congress on Computational Methods in Applied Sciences and Engineering, ECCOMAS 2012(pp. 5919-5924).
Shahgholi Ghahfarokhi, M. O. H. A. M. A. D. (2014). Experimental and numerical characterization of native bone tissue and glass ceramic bone scaffold at small scale.
Fada, R., Shahgholi, M., & Karimian, M. (2021). Improving the mechanical properties of strontium nitrate doped dicalcium phosphate cement nanoparticles for bone repair application. Ceramics International, 47(10), 14151-14159.
Fada, R., Farhadi Babadi, N., Azimi, R., Karimian, M., & Shahgholi, M. (2021). Mechanical properties improvement and bone regeneration of calcium phosphate bone cement, Polymethyl methacrylate and glass ionomer. Journal of Nanoanalysis, 8(1), 60-79.
Shahgholi, M., Oliviero, S., Baino, F., Vitale-Brovarone, C., Gastaldi, D., & Vena, P. (2016). Mechanical characterization of glass-ceramic scaffolds at multiple characteristic lengths through nanoindentation. Journal of the European Ceramic Society, 36(9), 2403-2409.
Karimipour, A., Malekahmadi, O., Karimipour, A., Shahgholi, M., & Li, Z. (2020). Thermal conductivity enhancement via synthesis produces a new hybrid mixture composed of copper oxide and multi-walled carbon nanotube dispersed in water: experimental characterization and artificial neural network modeling. International Journal of Thermophysics, 41(8), 1-27.
Alibabaei, S., Kasiri-Asgarani, M., & Bakhsheshi-Rad, H. (2019). Investigating the effect of solid solution treatment on the corrosion properties of biodegradable Mg-Zn-RE-xCa (x= 0, 2.5) alloy. Journal of Simulation and Analysis of Novel Technologies in Mechanical Engineering, 12(4), 67-80.
Ashouri, H. (2019). Evaluation of Thermal Barrier Coating in Low Cycle Fatigue Life for Exhaust Manifold. Journal of Simulation and Analysis of Novel Technologies in Mechanical Engineering, 12(4), 41-51.
Shokrieh, M. M., Heidari-Rarani, M., & Rahimi, S. R. (2009). Numerical Determination of Delamination Onset in Laminated Symmetric DCB Specimen. Journal of Simulation and Analysis of Novel Technologies in Mechanical Engineering, 2(2), 37-46.
Fatahi-Vajari, A. (2021). A new method for determination of natural frequency in bending vibration mode of single-walled carbon nanotubes. Journal of Simulation and Analysis of Novel Technologies in Mechanical Engineering, 13(1), 5-18.
