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These advanced materials captured the attention of the scientific community due to their wide range of applications.
Ain Shams Engineering Journal 5(3) (2014) 839-850
Key Engineering Materials, Trans Tech Publ. (2015)
Basri, A review on the fabrication techniques of functionally graded ceramic-metallic materials in advanced composites.
Materials Science and Engineering: A 764 (2019)

Perez1, f* 1Nanotechnology Research Laboratory, Department of Chemical Engineering, University of the Philippines Diliman, Quezon City, Philippines 2Laboratory of Electrochemical Engineering, Department of Chemical Engineering, University of the Philippines Diliman, Quezon City, Philippines aedgarclydelopez09@gmail.com, bnicolesaputil@gmail.com, claloza@up.edu.ph, dfgcamiguing@up.edu.ph, emlmopon@up.edu.ph,and fjdperez@up.edu.ph Keywords: Titanium dioxide nanotubes, Co-doping, Photoelectrocatalysis, Response surface methodology Abstract.
Recently, electrochemical advanced oxidation processes gained attention due to their ability to generate ROS in-situ [4–7].
Panizza, Electrochemical advanced oxidation processes: Today and tomorrow.
Vilar, Electrochemical advanced oxidation processes: A review on their application to synthetic and real wastewaters, Appl.
Forum. 950 (2019) 149–153

Introduction Increasing demands on weight reduction, safety and cost have led to a rapid development in car body engineering.
Advanced High Strength Steels (AHSS) are being intensively explored by the automotive industry [1, 2].
Forum Vol. 539-543(2007), p. 3967
Journal of Engineering Materials and Technology (Transactions of the ASME) Vol. 129(2007), No 3, p. 446

Encapsulation of Multi-Enzymes on Waste Clay Material: Preparation, Characterization and Application for Tapioca Starch Hydrolysis Nurul Aini Edama1,a, Alawi Sulaiman1,b, Ku Halim Ku Hamid2,c, Siti Noraida Abd Rahim1,d, Azhari Samsu Baharuddin3,e, Mohd Noriznan Mokhtar3,f 1Tropical Agro-Biomass Research Group, Faculty of Plantation and Agrotechnology, Universiti Teknologi MARA, Shah Alam, Malaysia 2Faculty of Chemical Engineering, Universiti Teknologi MARA, Shah Alam, Malaysia 3Department of Process and Food, Faculty of Engineering, Universiti Putra Malaysia, Serdang, Malaysia aainiedama@yahoo.com, bdr_alawi@salam.uitm.edu.my, cmaulana_kuhalim@yahoo.co.uk, daida7627@yahoo.com, eazharis@upm.edu.my, fnoriznan@upm.edu.my Keywords: Waste Clay, Enzyme Encapsulation, Immobilization Yield, FTIR, FESEM Abstract.
Rahim, "Physico-chemical and Morphological Changes of Sayong Kaolinite Clay Treated with Sulphuric Acid for Enzyme Immobilization," Advanced Material Reseach, vol. 832, pp. 589-595, 2014
Sayong Clay Material for Biocatalyst Immobilization," Material Science Forum, vol. 737, pp. 145-152, 2013

SOFC Forum, Poster B0512, 30.06-04.07.2008, Lucerne, Switzerland [3] Meulenberg W.A., Menzler N.H., Buchkremer H.P., Stöver D.: Manufacturing routes and state-of-the-art of the planar Jülich anode supported concept for solid oxide fuel cells.
Proc. 25 (3) (2004), 387-392 [6] Ettler M., Menzler N.H., Buchkremer H.P., Stöver D.: Characterization of the re-oxidation behaviour of anodesupported SOFCs; Advances in Solid Oxide Fuel Cells IV: Ceramic Engineering and Science Proceedings (Eds.: P.
Bansal) 29 (5), (2008), [7] Ivers-Tiffée E., Timmermann H., Leonide A., Menzler N.H., Malzbender J.: Methane reforming kinetics, carbon deposition, and redox durability of Ni/8 yttria-stabilized zirconia (YSZ) anodes; Handbook of Fuel Cells - Fundamentals, Technology and Applications, Vol. 5: Advances in Electrocatalysis, Materials, Diagnostics and Durability (Eds.: W.
PhD thesis, Ruhr University Bochum, Faculty of Mechanical Engineering, Germany (2008); available in German only (English translation: Influence of redox cycling on the operational stability of anodesupported SOFCs)

Box 2033, SE-550 02 Jönköping, Sweden 2Jönköping University, Dept. of Mechanical Engineering/Material and Manufacturing Casting, Box 1026, SE-551 11 Jönköping, Sweden avasilios.fourlakidis@swerea.se, blucian-vasile.diaconu@ju.se, cattila.dioszegi@ju.se Keywords: Tensile strength, lamellar graphite iron, primary austenite, pearlite spacing.
As seen in Fig. 4 the crack advanced at the periphery of some intact dendrite arms meaning that the dendrites poses much higher resistance to the crack growth in comparison with the eutectic phase [10].
Baker, The fracture resistance of the flake graphite cast iron, Materials in Engineering Applications 1 (1978) 13-18
Svensson, Fracture mechanics of lamellar cast iron, Solidification and Gravity V, Trans Tech Publications, Switzerland, Materials Science Forum 649 (2010), 517-522

Bolfarini Federal University of São Carlos, Department of Materials Engineering C.P. 676, 13565-905, São Carlos - SP, Brazil Keywords: white cast iron, retained austenite, spray forming.
Stekly, Surface Engineering, v. 9, n. 3, (1993), p. 231-240
Kiminami, C.Bolfarini, Advanced Powder Technology III- Materials Science Forum, v. 416-4, (2003), p. 419-424

Vaughan White 2,b , Ben Rumsey 2 and Hayley Woolf2 1MacDiarmid Institute for Advanced Materials and Nanotechnology, Victoria University of Wellington, P.O.
Forum, Vol. 34-36, (1988), p.599
Key Engineering Materials Vol. 264-268 (II), (2004), p. 889
Key Engineering Materials Vol. 206-213, (2002), p.51

Basilia1,2,3,d 1Materials Science Division, Industrial Technology Development Institute, Department of Science and Technology, Bicutan, Taguig City 1631, Philippines 2School of Chemical, Biological, and Materials Engineering and Sciences, and 3School of Graduate Studies, Mapúa University, Manila 1002, Philippines aclcustodio@mymail.mapua.edu.ph, bjmcabanerojr@gmail.com, cmapaglicawan@itdi.dost.gov.ph, dbabasilia@itdi.dost.gov.ph Keywords: abaca (Musa textilis), microcrystalline cellulose, polylactic acid, 3D printing, additive manufacturing, mechanical properties Abstract.
MCC fibers were manually mixed with PLA pellets at different fiber loadings (0-3 wt%, Table 1) prior to extrusion using a twin-screw extruder (Labtech Engineering Co.
We are also grateful for the technical support provided by the Advanced Device and Materials Testing Laboratory (ADMATEL), and the Standards and Testing Division (STD) of the Industrial Technology Development Institute (ITDI) of the Department of Science and Technology (DOST), Philippines.
Materials Science Forum, 1015 MSF, 64–69. https://doi.org/10.4028/www.scientific.net/MSF.1015.64 [4] E.

Fe-based amorphous/nanocrystalline coating on AZ91 magnesium alloy substrate deposited by automatic high velocity arc spraying Linlei Wang1, a, Xiubing Liang1,2, b, Shicheng Wei1,c, Yongxiong Chen1, d, Wei Guo1, e, Huadong Ding1, f 1Science and Technology on Remanufacturing Laboratory, Academy of Armored Force Engineering, No.21, Dujiakan, Fengtai District, Beijing,100072, China 2Department of Scientific Research, Academy of Armored Forces Engineering, No.21, Dujiakan, Fengtai District, Beijing,100072, China awanglinlei1129@163.com, bliangxiubing@yahoo.com.cn,cwsc33333@163.com dyongxiongchen@yahoo.cn, egwhy@163.com, fdinghuadong@163.com Keywords: Fe-based amorphous/nanocrystalline coating; Automatic high velocity arc spraying; Mechanical properties; Magnesium alloy.
Mg alloys are advanced light structural and functional materials being increasingly used in the automotive, aerospace, military equipment, electronic and energy industries, owing to their high strength-to-weight ratio, high thermal conductivity and good recycling with low energy consumption[7].
Mater Sci Forum 488 (2005) 685-688 [17] J.B.