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Marsden: Engineering Fracture Mechanics Vol. 68 (10) (2001), p. 1171
Gogotsi: Ceramics International Vol. 29 (2002), p. 777
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Furthermore, advancement in the processing technique is essential in order to evolve a ceramic composite which can also be utilized in other engineering applications.
Engineering Materials; PHI Learning Private Limited: New Delhi, 2011
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Materials Science and Engineering: A-Structural Mater Prop Microstruct Process 2012, 546, 328–331
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This volume of the journal contains papers presented at the 4th International Conference on Material Engineering and Application (4th ICMEA 2019, Malaysia, August 23-25, 2019).
This collection will be useful for specialists from many branches of engineering sciences and modern production.
Steel, Alloys, Mechanical Properties, Building Materials, Geopolymer, Nanomaterials, Coatings, Corrosion, Cladding, Thin Films, Polymers, Composites, Graphene, Plastic Deformation, Forming, Waste Recycling, Ceramics, Fibres, Electrochemical Synthesis, Membranes, Welding, Injection Moulding

The special edition of the journal “Key Engineering Materials” contains papers that were presented to the 58th International Conference of Materials Science and Applied Chemistry (MSAC 2017, 20th October, 2017, Riga, Latvia).
Biomaterials, Medicinal Chemistry, Waste Recycling, Environmental Engineering, Biotechnologies, Polymers and Composites, Membranes, Thin Films, Functional Ceramics and Metal Oxides, Steels and Alloys, Textile Technology

Slurry Erosive Wear Characteristics of Engineering Ceramics for Hydraulic Machinery Juan Liu 1, Longhao Qi2,*, Hongyuan Xu 1 and Hezhuo Miao 2 1 Dept. of Thermal Engineering, Tsinghua University, Beijing, 100084, China 2 Dept. of Materials Sci. and Engineering, Tsinghua University,Beijing, 100084, China Keywords: Ceramics, Erosive wear, Hydraulic machinery, Wear mechanism Abstract.
Engineering ceramics have a high application potential for wear-protection of different equipment used for electric power generating, mining and mineral industries.
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Zhang: Journal of Hebei Institute Techbology Vol. 20(1998), pp. 29

However, poor reliability and resistance to damage resulted from brittleness and low toughness limits its application for engineering [3].
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International Journal of Impact Engineering, 1998, 21(4): 245-265
International Journal of Impact Engineering, 2004, 24(6/7): 597-611
Modeling prestressed ceramic and its effect on ballistic performance [J].International Journal of Impact Engineering, 2005, 31(2): 113-127.

Investigation on Axial Turning-Grinding of Engineering Ceramics[J].
Mechanism Analysis of High Efficiency Axial Turn-grinding of Engineering Ceramics[J].
Key Engineering Materials,2011
Study on Axial Turning of Engineering Ceramics [J].
Precision Engineering: Journal of the International Societies for Precision Engineering and Nanotechnology,2001,25(4):274~283

This journal issue presents materials from the 13th International UNIMAS Engineering Conference 2020 (EnCon 2020), which was held online by University Malaysia Sarawak, Sarawak, Malaysia, with the theme "Empowering industry and transforming society through engineering, technology, and management".
The collected papers describe the current research results in the areas of materials engineering and processing technologies with a specific focus on the use of bio- and biodegradable materials in channeling various applications in numerous branches of human activity.
Biomaterials, Bio-Waste, Biocomposites, Natural Fibre, Hydroxyapatite, Ceramics, Thin Film, Mechanical Properties, Geopolymer, Concrete, Slag, Fly Ash, Lateritic Soil, Biodiesel, Microbial Electrolysis Cell, Sequencing Batch Reactor, Microplastic, Adsorbent, Bio-Waste Recycling, Nanoparticles

Malkin: Grinding Mechanisms and Energy Balance for Ceramics, Transaction of ASME: Journal of Manufacturing Science and Engineering, Vol.121 (1999), pp.623-631
Scattergood: Ductile-regime: a New Technology for Machining Brittle Materials, Transaction of ASME: Journal of Engineering for Industry, Vol.113 (1991), pp.184-189
Watanabe: Super High Speed Grinding for Ceramics with Vitrified Diamond Wheel, International Journal of Japan Society for Precision Engineering, Vol.28 (1994), pp.344-345
Yin: Grinding Characteristics of Engineering Ceramics in High Speed Regime, International Journal of Abrasive Technology, Vol.1 (2007), pp.78-93
Xiong: Experimental Investigations of Advanced Ceramics in High Efficiency Deep Grinding, Chinese Journal of Mechanical Engineering, Vol.43 (2007), pp.176-184

Identification of Brittle-Ductile Material Removal Characteristics in Ultrasonic aided Lapping of Engineering Ceramics F.
Journal of Engineering for Industry.
International Conference on Optical Engineering for Sensing and Nanotechnology, 1999 [4] Ke Hongfa, Zhang Yaohui, et al.
[6] Tian Xinli, Yu Aibing: Theory and Technology of Engineering Ceramic Machining.
Precision Engineering.