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Keywords: concrete, heat-resistant properties, aggregates, aluminum oxide (electrocorundum) materials.
Sciences, Saratov, 1997
Rossignol, Use of silicon carbide sludge to form porous alkali-activated materials for insulating application, European physical journal-special topics, 224(9) (2015) 1725-1735
Al-Hawas, Effects of key factors on compressive and tensile strengths of concrete exposed to elevated temperatures, Arabian journal for science and engineering, 39(6) (2014) 4507-4513
Sciences, Moscow, 1987.

Zherebchenko, Biologically active surgical sutures materials (literature review), Upper Volga Medical Journal 10 (4) (2012) 21-28
, Materials Science and Engineering: C 62 (2016) 960-966
Series: Materials Science and Engineering 966 (2020) 012122
Yashiro, Design and mechanical properties of new β type titanium alloys for implant materials, Materials Science and Engineering A, 243 (1-2), (1998), 244-249
Chung, A review of exfoliated graphite, Journal of Materials Science 51 (2015) 9284-6

Pai, Reinforcement coatings and interfaces in aluminum metal matrix composites, Journal of Materials Science. 33 (1998) 3491-3503
Degisher, Interlayer structure of carbon fiber reinforced aluminum wires, Journal of materials science. 35 (2000) 2279-2289
Scott, Interface and fracture of carbon fibre reinforced Al-7wt% Si alloy, Journal of materials science. 26 (1991) 1609-1617
Hall, Fibre and fibre-surface treatment effects in carbon/aluminum metal matrix composites, Journal of Materials Science. 27 (1992) 2093-2100
Materials Science Forum. 217 (1996) 153-158

Materials and equipment.
Determination of characteristics of loose materials.
Mi, Extinguishing performance of alcohol-resistant firefighting foams on polar flammable liquid fires, Journal of Fire Sciences, 38(1) (2019) 53–74
Mi, Extinguishing performance of alcohol-resistant firefighting foams on polar flammable liquid fires, Journal of Fire Sciences, 38(1) (2019) 53–74
Bezuglov, Mathematical Modeling of Fire-Proof Efficiency of Coatings Based on Silicate Composition, Materials Science Forum, 1006 (2020) 70–75

Beijing: China building materials science research institute. 2003
Journal of Shandong Institute of Building Materials. 6(1998) 3-5
Journal of Building Materials. 15 (2012) 589-594
Journal of Beijing university of science and technology. 12 (2012)1380-1384
Journal of Guizhou Science. 31 (2013)35-38

Introduction The wall material, the largest use of a building material, is about 70% of total building materials.
Cases Study Now we have 5 wall materials available.
Ma: Building Science, Vol. 23 (2007), pp. 19-23
Wang: Journal of Chang’ an University (Natural Science Edition), Vol. 26 (2006), pp. 57-60
Wang: Journal of Engineering Management, Vol. 24 (2010), pp. 398-410

Microstructural Characterization of “New” 2.5D Woven Reinforcement Materials DianTang ZHANG1, a, Ying SUN1, b, Wei HAI1, c, Li CHEN1, d, Ning PAN1, 2, e 1 MEKL of Advanced Textile Composite Materials, Institute of Textile Composites, Tianjin Polytechnic University, Tianjin 300160, China 2 Fiber and Polymer Science Division of Textiles, Biological and Agricultural Engineering, The University of California at Davis, the United States of America a zhangdt787@126.com, b sunying@tjpu.edu.cn, c haiwei108@126.com, d chenli@tjpu.edu.cn, e npan@ucdavis.edu Keywords: Composites; 2.5D woven; Normal yarns reinforced; Geometry model; Fiber materials Abstract.
So, 2.5D woven fabrics with normal yarns acclaimed as “New” 2.5D woven reinforcement materials are becoming perfect reinforcement materials for carbon and ceramic matrix composites.
As mentioned above, there is no reference relating with the geometry model about normal yarns reinforced 2.5D woven materials.
, , , (3) Where T (tex) is yarn fineness. ρ (g/cm3) is the density of fiber materials.
[4] DONG Weifeng, XIAO Jun, LI Yong: Journal of Nanjing University of Aeronautics＆Astronautics.

The experimental design of similar materials of coal In the testing of coaly similar materials, you need to consider the similarity, so you must first determine the various physical and mechanical parameters of coal, and in accordance with this parameter to select similar raw materials.
According to the selected raw materials ratio, all the formula tables were obtained.
Su: Rock Mechanics and Engineering Journal, Vol.21 (2002) No.12, p.1827–1830
Di: Rock Mechanics and Engineering Journal, Vol.21 (2002), No.12, p.1667–1671
Fan: Journal of Jilin University (engineering science edition), Vol.38 (2008) No.2, p.399–403

As a result of the diverse structure and specific properties associated with the small thickness of such objects, their physical characteristics can differ significantly from those of the same materials in the massive state.
In the past decades, many materials have been studied [8-10], but copper (Cu) attracts more attentions since it is hard to form the intermetallic compound with Cu/Si, thereby providing a relatively stable interface between them.
D. 2015 Advanced interconnects: materials, processing, and reliability ECS Journal of Solid State Science and Technology. 4(1) Y1-Y4 [4] Shang J., Hao J.
H. 2000 Adhesion and reliability of copper interconnects with Ta and TaN barrier layers Journal of Materials Research. 15(1) 203-211
K. 2004 Chemical mechanical planarization for microelectronics applications Materials Science and Engineering: R: Reports. 45(3-6) 89-220 [11] Wrschka P., Hernandez J., Oehrlein G.

Pandey Journal of Magnetism and Magnetic Materials 321 (2009) 4001-4005
Shin Journal of Crystal Growth 291 (2006) 328-333
Wu Materials Science and Engineering B 111 (2004) 197-206
Ye Materials Science and Engineering B 121 (2005) 42-47
Fan Journal of Alloys and Compounds 424 (2006) 304-306