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[18] M.F. de Campos: Materials Science Forum Vols. 591–593 (2008), p. 8
Castro, M.F.de Campos: Journal of Magnetism and Magnetic Materials Vol. 328 (2013), p. 53
Missell: Journal of Magnetism and Magnetic Materials Vol. 320 (2008), p. e73
[21] M.F. de Campos: Materials Science Forum Vols 775-776 (2014), p. 437
[22] M.F. de Campos, F.A.S. da Silva, J.A. de Castro: Materials Science Forum Vols. 775-776 (2014), p. 431.

Study on Microwave - Assisted Extraction of the Yellow Pigment from Orange Peel Xiuhua Tang School of Material and Chemical Engineering, Sichuan University of Science& Engineering,Zigong,643000,Sichuan,China Sxb741021@126.com Keywords: Orange peel, Yellow pigment, Microwave extraction, Extraction percent.
The MAS-1 atmospheric microwave-assisted sythesis/extraction reaction apparatus(Shanghai XinYi Microwave Chemistry Science And Technology Company Limited).DK98-IIA thermostatic water bath(Tianjin Tester Instrument Company Limited),SHB-3 versatile circulating water vacuum(Dufu Equipment factory of Zhengzhou), DHG-9070B thermostatic and drying oven(Shanghai Lang Xuan Experimental Company Limited), the AR1140 type electronic balance(METLER TOLEDO-United States of Equipment Company Limited), TDL-40B low speed centrifigue(Beijing Xing Shi Li He Science And Technology Development Company Limited), etc.
References [1] Zongya Tao,Xiaoqiong Duan,Xiao Du, Extraction of yellow pigment from orange peeland research of properties, Journal of Sichuan normal university(natural science edition), 28(2005):727-732
[2] Youji Li,Zhijuan Song,Hongxian Tian, Process research on extraction of yellow pigment from orange peel, Journal of food and fermentation industry, 28(2002):32-34
[3] Jianming Shao,Yuhong zang, Progress in effective components of orange slag, Chengde Petroleum College journal , 2(2011):31-36

Andersen, Journal of Meat Science, 89,111 (2011)
Bertram, Journal of Meat Science, 72, 34 (2006)
Andersen, Journal of Meat Science, 66, 301 (2004)
Karlsson, Journal of Meat Science, 66, 437 (2004)
Aaslyng, Journal of Meat Science, 77, 190 (2007)

Progress in Materials Science. 2009; 54:397-425
Materials Science and Engineering: C. 2017; 70:264-71
Materials Science and Engineering: C. 2021;119: 111503
Journal of Materials Science: Materials in Electronics. 2015; 26:317-21
Materials Science and Engineering: C. 2003; 23:551-60.

So Fe3O4/graphene composites are better anode materials than Fe3O4 microspheres.
So Fe3O4/graphene composites are better anode materials than Fe3O4 microspheres.
CuO/graphenecomposite as anode materials for lithium-ion batteries, Electrochimica Acta, 2011, 56: 2306
Highly porous reticular tin–cobalt oxide composite thin film anodes for lithium ionbatteries, Journal of Materials Chemistry, 2009, 19: 8360
Graphene based materials: past, present and future, Progress in Material Science, 2011, 56: 1178–1271

Nanjing University of Science and Technology,2013
The performance of ruthenium oxide / graphene composite material supercapacitor [J].Materials and Structures，2013，50（6）：347-352
Materials Letters, 2012, 76: 127-130
Ordnance material science and Engineering, 2014, 37（3）
Journal of electrochemistry, 2013, 19(4):361-369

Analysis of Mechanical Performance and Microstructure of Steel Slag Processed with Accelerated Carbonation Qisheng Wu1,a*, Hongxia Gu2,b, Tao Yang1,c, Changsen Zhang1,d, Zhian Min3,e, Yang Wu2,f 1School of Materials Science and Engineering, Yancheng Institute of Technology, Jiangsu Yancheng, 224051, China 2School of Materials Science and Engineering, Jiangsu University, Jiangsu Zhenjiang, 212013, China 3College of Materials Science and Engineering, Beijing University of Chemical Technology, Beijing, 100029, China aqishengwu@ycit.cn, b2287840185@qq.com, c370341662@qq.com, dzcs@ycit.cn, e782179783@qq.com, f1131574406@qq.com Keywords: Steel slag; Carbonation; Pressure Steaming; Calcium and Magnesium Carbonate; Spurrite Abstract.
Experiments Pretreatment and Characterization of Raw Materials.
Performance evaluation for carbonation of steel-making slags in a slurry reactor, Journal of Hazardous Materials. 186(1) (2011) 558
Leaching modelling of slurry-phase carbonated steel slag, Journal of Hazardous Materials. 302 (2015) 415
Carbonated Ladle Slag Fines for Carbon Uptake and Sand Substitute, Journal of Materials in Civil Engineering. 21(11) (2009) 657-665

Materials and Methods All materials used in this work were illustrated in Table 1.
Table 1: The Materials were used in PVA foam preparation.
Hashim, Bio-application of Poly (Vinyl Alcohol) /Biphasic Calcium Phosphate Scaffold as Bone Tissue Replacement, Current Materials Science. 15 (2022) 271 – 279
A, Impact and Flexural Strength of Kaolinite Glass Fibers Reinforced Heat-Cured Acrylic Denture, Materials Science Forum. 1002 (2020) 340-3##
Nair, A biodegradable and biocompatible PVA–citric acid polyester with potential applications as matrix for vascular tissue engineering, Journal of Materials Science: Materials in Medicine. 20 (2009) 259-269,

Obikawa: Adiabatic shear in chip formation with large negative rake angle, International Journal of Mechanical Sciences 47 (2005), p. 1377-1392 [2] Y.
Dewes: 3D FE modelling of the cutting of Inconel 718, Journal of Materials Processing Technology 150 (2004), p. 116-123 [16] A.
Rigal: A contribution to a qualitative understanding of thermo- mechanical effects during chip formation in hard turning, Journal of Materials Processing Technology, Vol 176 (2006), p. 214-221 [19] A.
Woodbury: Dynamic Material Behaviour Modeling Using Internal State Variable Plasticity and Its Application in Hard Machining Simulations, Journal of Manufacturing Science and Engineering, Vol. 128 (2006), p.749-759 [21] H.
Hollmann, High speed cutting of metal-based materials, Wiley-VCH, Weinheim (2005), p. 470-49

Dobrzański, Wojciech Pakieła*, Krzysztof Labisz, Marek Roszak, Błażej Tomiczek Division of Materials Processing Technology, Management and Computer Techniques in Materials Science, Institute of Engineering Materials and Biomaterials, Silesian University of Technology, Konarskiego Str 18A, 44-100 Gliwice, Poland Tomasz.Tanski@polsl.pl, Leszek.Dobrzański.polsl.pl, Wojciech.Pakiela@polsl.pl, Krzysztof.Labisz@polsl.pl, Marek.Roszak@polsl.pl, Blazej.Tomiczek@polsl.pl Keywords: Laser surface treatment, Laser feeding, surface engineering, tribological test, aluminium alloy, ball on plate Abstract.
The hardness of both materials after laser feeding was classified on the same level.
Dobrzanski, Structure and mechanical properties of gradient coatings deposited by PVD techniques onto the X40CrMoV5-1 steel substrate, Journal of Materials Science 43 (2008) 4300-4307
Proc. of SPIE Vol. 8703, Laser Technology 2012: Applications of Lasers, 87030T (January 22, 2013), DOI: 10.1117/12.2013431 [11] Wegrzyn T., Piwnik J., Low alloy welding with micro-jet cooling, Archives of Metallurgy and Materials, vol 57, iss 2, 2012, [12] Dobrzański L.A., Sitek W., Krupiński M., Computer aided method for evaluation of failure class of materials working in creep conditions, JOURNAL OF MATERIALS PROCESSING TECHNOLOGY, Vol. 157 (2004) 102-106
Maniara R, Sokolowski J., Kasprzak W., Krupinski M., Brytan Z., Applications of the artificial intelligence methods for modeling of the ACAlSi7Cu alloy crystallization proces, Journal Of Materials Processing Technology,Vol. 192, 582-587, 2007