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Online since: October 2006
Authors: Kurosch Rezwan, Ludwig J. Gauckler
The protein adsorption process is of great interest in order to understand better the biointegration of implant
materials, with the long-term objective of synthesizing either fully biocompatible
materials or, in the ideal case, truly bio-active materials to replace current
materials.
However, cell adhesion, again, is dependent on protein adhesion on materials and protein interactions with materials.
Nose: Journal of Biomedical Materials Research Vol. 40 (1998), p. 24-30 [4] D.
Rouwendal: Journal of Colloid and Interface Science Vol. 139 (1990), p
Muller: Journal of Biomedical Materials Research Vol. 39 (1998), p. 478-485 [24] B.
However, cell adhesion, again, is dependent on protein adhesion on materials and protein interactions with materials.
Nose: Journal of Biomedical Materials Research Vol. 40 (1998), p. 24-30 [4] D.
Rouwendal: Journal of Colloid and Interface Science Vol. 139 (1990), p
Muller: Journal of Biomedical Materials Research Vol. 39 (1998), p. 478-485 [24] B.
Online since: August 2022
Authors: Yasir Nawab, Muhammad Shahid, Arif Ali Shah, Naveed Ahmed Siddiqui
Two elastomeric materials i.e.
Introduction Materials that exhibit negative Poisson’s ratio (NPR) under tensile load are termed as auxetic materials.
Alderson, Auxetic materials: Functional materials and structures from lateral thinking.
Advanced Materials 12 (2000) 617–628
Journal of Composite Materials 38 (2004)95–106
Introduction Materials that exhibit negative Poisson’s ratio (NPR) under tensile load are termed as auxetic materials.
Alderson, Auxetic materials: Functional materials and structures from lateral thinking.
Advanced Materials 12 (2000) 617–628
Journal of Composite Materials 38 (2004)95–106
Online since: December 2013
Authors: Ai Dong Xu, Ming Zhe Liu, Chen Xi Wang
Research on the material transportation automation technology based on SEMI standard
Chenxi Wang 1, a, Mingzhe Liu1, b and Aidong Xu1, c
1Shenyang institute of Automation Chinese Academy of Sciences, Shenyang China
a wangchenxi@sia.cn, b lmz@sia.cn, c xad@sia.cn
Keywords: SEMI Standard, semiconductor, material transportation, FA.
Process of material transportation communication The process of material transportation communication is shown as Fig. 3.
Acknowledgments This paper is supported by the key laboratory of Chinese Academy of Sciences: Lab.
Research on SEMI standard model device control semiconductor, Chinese Journal of scientific instrument (fourth suppl.) 2008,4.
Design of semiconductor process equipment simulation system based on SEMI standard, electronic information materials and devices 2012, 4.
Process of material transportation communication The process of material transportation communication is shown as Fig. 3.
Acknowledgments This paper is supported by the key laboratory of Chinese Academy of Sciences: Lab.
Research on SEMI standard model device control semiconductor, Chinese Journal of scientific instrument (fourth suppl.) 2008,4.
Design of semiconductor process equipment simulation system based on SEMI standard, electronic information materials and devices 2012, 4.
Online since: July 2014
Authors: Joel Hemanth, G. Purushotham
This method is the most economical to fabricate composites materials.
Journal of composite materials, vol.43, No.06/2009
Rohatgi, Metal matrix composites, Defense Science Journal, vol 43, No:4, Oct 1993, pp323-349
[4] Meenu Srivastava, A Srinivasan, VK William Grips Influence of Zirconica incorporation on the mechanical & chemical properties of Ni-Co alloys, American Journal of material science, 2011, 113-122
International symposium of research students on material science & engineering, Dec 20-22, 2004, Chennai
Journal of composite materials, vol.43, No.06/2009
Rohatgi, Metal matrix composites, Defense Science Journal, vol 43, No:4, Oct 1993, pp323-349
[4] Meenu Srivastava, A Srinivasan, VK William Grips Influence of Zirconica incorporation on the mechanical & chemical properties of Ni-Co alloys, American Journal of material science, 2011, 113-122
International symposium of research students on material science & engineering, Dec 20-22, 2004, Chennai
Online since: September 2019
Authors: Igor A. Polozov, Evgenii Borisov, Vadim Sufiiarov
Materials Science Forum.
Journal of Materials Science 52.20 (2017): 12476-12485
Materials & Design 104 (2016): 197-204
Materials & Design 100 (2016): 291-299
IOP Conference Series: Materials Science and Engineering, 2017, Vol. 192.
Journal of Materials Science 52.20 (2017): 12476-12485
Materials & Design 104 (2016): 197-204
Materials & Design 100 (2016): 291-299
IOP Conference Series: Materials Science and Engineering, 2017, Vol. 192.
Online since: September 2020
Authors: Aleksandr Volodchenko
Shoukhov, 46 Kostyukov str., Belgorod, 308012, Russia
alex-0904@mail.ru
Keywords: Non-autoclaved silicate materials, hydrothermal synthesis, unconventional aluminosilicate raw materials, artificial calcium hydro silicates, aluminosilicate binders, building materials
Abstract.
Along with widely used hydration hardening materials based on the cement systems in construction, silicate materials of autoclave hardening are also used [11-12].
Chulenyov, Role of solutions when metasomatic transformations in construction composites, Materials Science Forum. 974 (2019) 168–174
Strokova, Development of scientific bases for production of silicate autoclave materials using clay raw materials, Construction Materials. 9 (2018) 25–31
Glagolev, On the issue of reducing the energy intensity of the silicate composites production with the unconventional aluminosilicate raw materials use, Materials Science Forum. 974 (2019) 20 –25.
Along with widely used hydration hardening materials based on the cement systems in construction, silicate materials of autoclave hardening are also used [11-12].
Chulenyov, Role of solutions when metasomatic transformations in construction composites, Materials Science Forum. 974 (2019) 168–174
Strokova, Development of scientific bases for production of silicate autoclave materials using clay raw materials, Construction Materials. 9 (2018) 25–31
Glagolev, On the issue of reducing the energy intensity of the silicate composites production with the unconventional aluminosilicate raw materials use, Materials Science Forum. 974 (2019) 20 –25.
Online since: August 2024
Authors: Harira Prada, Ima Safriza, Gaustama Putra
The process of making MR Suandi bricks uses water and clay as raw materials.
This research aims to look at the compressive strength quality of bricks using standard raw materials and additional raw materials.
Material There are several raw materials used in making bricks at UD.
The raw materials used in this research are : a.
Journal of Engineering and Computer Science, 2(2), 13-18
This research aims to look at the compressive strength quality of bricks using standard raw materials and additional raw materials.
Material There are several raw materials used in making bricks at UD.
The raw materials used in this research are : a.
Journal of Engineering and Computer Science, 2(2), 13-18
Online since: May 2014
Authors: Rainer Gadow, Frank Kern, Richard Landfried
It was found that the use of zirconia as matrix material does improve the toughness and strength compared to alumina based composites whereas the drawback of zirconia based materials concerning machinability and lower hardness can be only partially compensated by adjusting the titanium carbide content.
Electrical discharge machining (EDM) is an established process for machining of materials with high hardness such as hardened steel or cemented carbides for mold design and construction.
References [1] Chevallier, J.; Gremillard, L.: “Zirconia as a Biomaterial”, Comprehensive Biomaterials, Elsevier, , Volume 1: Metallic, Ceramic and Polymeric Biomaterials (2011) 95-108 [2] Hannink, R.H.J.; Kelly, P.M.; Muddle, B.C.: “Transformation Toughening in Zirconia-Containing Ceramics”, Journal of the American Ceramic Society, 83 [3] (2000) 461-487 [3] Claussen, N.: “Fracture Toughness of Al2O3 with Unstabilized ZrO2 Dispersed Phase”, Journal of the American Ceramic Society, 59, 1-2 (1976) 49-51 [4] Becher, P.F.: “Slow Crack Growth Behavior in Transformation-Toughened Al2O3-ZrO2(Y2O3) Ceramics”, Journal of the American Ceramic Society, 66 [7] (1983) 485-488 [5] Lange, F.F.: “Transformation toughening – Part 4 Fabrication, fracture toughness and strength of Al2O3-ZrO2 composites”, Journal of Materials Science, 17 (1982) 247-254 [6] Fukuzawa, Y.; Tani, T.; Iwane, E.; Mohri, N.: “A New Machining Method for Insulating Ceramics with an Electrical Discharge Phenomenon”, Journal of
the Ceramic Society of Japan, 103, 10 (1995) 1000-1005 [7] Liu, Y.H.; Ju,R.J.; Li, X.P.; Yu, L.L.; Zhang, H.F.: “Electric discharge milling of insulating ceramics”, Proceedings of the Institution of Mechanical Engineers, Part B: Journal of Engineering Manufacture, 222 (2008) 362-366 [8] Fukuzawa, Y.; Mohri, N.; Gotoh, H.; Tani, T.: “Three-dimensional machining of insulating ceramics materials with electrical discharge machining”, Transactions of Nonferrous Metals Society of China, 19 (2009) 150-156 [9] Hösel, T.; Cvancara, P.; Ganz, T.; Müller, C.; Reinecke, H.: “Characterisation of high aspect ratio non-conductive ceramic microstructures made by spark erosion”, Microsystem Technologies, 17 (2011) 313-318 [10] Lauwers, B.; Kruth, J.P.; Eeraerts, W.; Schacht, B.; Bleys, P.: “Investigation of material removal mechanisms in EDM of composite ceramic materials”, Journal of Materials Processing Technology, 149 (2004) 347-352 [11] Salehi, S.; Van der Biest, O.; Vleugels, K.: “Electrically
-C.: Microstructure and tool electrode erosion in EDMed of TiN/Si3N4 composites, Materials Science and Engineering, A363 (2003) 221-227 [14] Liu, K.; Reynaerts, D.; Lauwers, B.: “Influence of the pulse shape on the EDM performance of Si3N4-TiN ceramic composite”, CIRP Annals – Manufacturing Technology, 58 (2009) 217-220 [15] Landfried, R.; Kern, F.; Burger, W.; Leonhardt, W.; Gadow, R.: “Wire-EDM of ZTA-TiC composites with variable content of electrically conductive phase”, Key Engineering Materials, Vols. 504-506 (2012) 1165-1170 [16] Landfried, R.; Kern, F.; Gadow, R.: “Electrical Discharge Machining of Alumina-Zirconia-TiC Composites with varying zirconia content”, Key Engineering Materials, Vols. 554-557 (2013) 1916-1921 [17] P.
Electrical discharge machining (EDM) is an established process for machining of materials with high hardness such as hardened steel or cemented carbides for mold design and construction.
References [1] Chevallier, J.; Gremillard, L.: “Zirconia as a Biomaterial”, Comprehensive Biomaterials, Elsevier, , Volume 1: Metallic, Ceramic and Polymeric Biomaterials (2011) 95-108 [2] Hannink, R.H.J.; Kelly, P.M.; Muddle, B.C.: “Transformation Toughening in Zirconia-Containing Ceramics”, Journal of the American Ceramic Society, 83 [3] (2000) 461-487 [3] Claussen, N.: “Fracture Toughness of Al2O3 with Unstabilized ZrO2 Dispersed Phase”, Journal of the American Ceramic Society, 59, 1-2 (1976) 49-51 [4] Becher, P.F.: “Slow Crack Growth Behavior in Transformation-Toughened Al2O3-ZrO2(Y2O3) Ceramics”, Journal of the American Ceramic Society, 66 [7] (1983) 485-488 [5] Lange, F.F.: “Transformation toughening – Part 4 Fabrication, fracture toughness and strength of Al2O3-ZrO2 composites”, Journal of Materials Science, 17 (1982) 247-254 [6] Fukuzawa, Y.; Tani, T.; Iwane, E.; Mohri, N.: “A New Machining Method for Insulating Ceramics with an Electrical Discharge Phenomenon”, Journal of
the Ceramic Society of Japan, 103, 10 (1995) 1000-1005 [7] Liu, Y.H.; Ju,R.J.; Li, X.P.; Yu, L.L.; Zhang, H.F.: “Electric discharge milling of insulating ceramics”, Proceedings of the Institution of Mechanical Engineers, Part B: Journal of Engineering Manufacture, 222 (2008) 362-366 [8] Fukuzawa, Y.; Mohri, N.; Gotoh, H.; Tani, T.: “Three-dimensional machining of insulating ceramics materials with electrical discharge machining”, Transactions of Nonferrous Metals Society of China, 19 (2009) 150-156 [9] Hösel, T.; Cvancara, P.; Ganz, T.; Müller, C.; Reinecke, H.: “Characterisation of high aspect ratio non-conductive ceramic microstructures made by spark erosion”, Microsystem Technologies, 17 (2011) 313-318 [10] Lauwers, B.; Kruth, J.P.; Eeraerts, W.; Schacht, B.; Bleys, P.: “Investigation of material removal mechanisms in EDM of composite ceramic materials”, Journal of Materials Processing Technology, 149 (2004) 347-352 [11] Salehi, S.; Van der Biest, O.; Vleugels, K.: “Electrically
-C.: Microstructure and tool electrode erosion in EDMed of TiN/Si3N4 composites, Materials Science and Engineering, A363 (2003) 221-227 [14] Liu, K.; Reynaerts, D.; Lauwers, B.: “Influence of the pulse shape on the EDM performance of Si3N4-TiN ceramic composite”, CIRP Annals – Manufacturing Technology, 58 (2009) 217-220 [15] Landfried, R.; Kern, F.; Burger, W.; Leonhardt, W.; Gadow, R.: “Wire-EDM of ZTA-TiC composites with variable content of electrically conductive phase”, Key Engineering Materials, Vols. 504-506 (2012) 1165-1170 [16] Landfried, R.; Kern, F.; Gadow, R.: “Electrical Discharge Machining of Alumina-Zirconia-TiC Composites with varying zirconia content”, Key Engineering Materials, Vols. 554-557 (2013) 1916-1921 [17] P.
Online since: January 2007
Authors: Joo Yung Jung, Gyeong Rak Choi, In Pil Kang, Jong Won Lee, Kwang Joon Yoon, Mark J. Schulz, Hyung Ki Park, Yeo Heung Yun, Vesselin N. Shanov
To address the need for new smart materials, this paper explores the use of carbon
nanotubes to develop a nanocomposite smart material having electrochemical impedance properties
for sensing and actuation.
Introduction Present smart materials and structures have fundamental limitations in their sensitivity, size, cost, ruggedness, and weight.
A new approach to develop smart structures is to develop intelligent electronic materials based on a conductive polymer matrix and carbon nanotubes.
Fabrication of Smart Nanoomposites Because of the CNTs small size and high surface area, fabricating functional macro scale materials has been a major challenge for applications such as high capacity energy storage, sensor materials, and electrochemical actuators.
Lockwood: Journal of Dispersion Science and Technology Vol. 23-1(2003), p. 1 24. 8.
Introduction Present smart materials and structures have fundamental limitations in their sensitivity, size, cost, ruggedness, and weight.
A new approach to develop smart structures is to develop intelligent electronic materials based on a conductive polymer matrix and carbon nanotubes.
Fabrication of Smart Nanoomposites Because of the CNTs small size and high surface area, fabricating functional macro scale materials has been a major challenge for applications such as high capacity energy storage, sensor materials, and electrochemical actuators.
Lockwood: Journal of Dispersion Science and Technology Vol. 23-1(2003), p. 1 24. 8.
Online since: December 2022
Authors: Mohammed Hamza Al-Maamori, Rola Abdul Al Khader Abbas
Journal of Macromolecular Science, Part B: Physics, 53(4), 645–661. https://doi.org/10.1080/00222348.2013.860304
[5] Dolog, R., & Weiss, R.
Journal of Polymer Science, Part B: Polymer Physics, 51(13), 1033–1040. https://doi.org/10.1002/polb.23301 [10] Kow, Y.
Journal of Materials Science, 55(25), 10975–11051. https://doi.org/10.1007/s10853-020-04761-w [13] Meng, Q., & Hu, J. (2009).
Journal of Polymer Science, Part B: Polymer Physics, 56(8), 673–688. https://doi.org/10.1002/polb.24578 [15] Safranski, D., & Griffis, J.
Journal of King Saud University - Science, 29(4), 494–501. https://doi.org/10.1016/j.jksus.2017.09.003 [18] Wu, X.
Journal of Polymer Science, Part B: Polymer Physics, 51(13), 1033–1040. https://doi.org/10.1002/polb.23301 [10] Kow, Y.
Journal of Materials Science, 55(25), 10975–11051. https://doi.org/10.1007/s10853-020-04761-w [13] Meng, Q., & Hu, J. (2009).
Journal of Polymer Science, Part B: Polymer Physics, 56(8), 673–688. https://doi.org/10.1002/polb.24578 [15] Safranski, D., & Griffis, J.
Journal of King Saud University - Science, 29(4), 494–501. https://doi.org/10.1016/j.jksus.2017.09.003 [18] Wu, X.