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Stevenson 4, m 1 School of Electrical, Electronic and Computer Engineering, University of Newcastle, Newcastle, NE1 7RU, UK 2 Department of Physics, University of Coimbra, P-3004-516 Coimbra, Portugal 3 School of Chemical Engineering and Advanced Materials, University of Newcastle, Newcastle, NE1 7RU, UK 4 Scottish Microelectronics Centre, University of Edinburgh, Edinburgh, EH9 3JL, UK a J.M.dos-Santos@ncl.ac.uk, b zepina@ci.uc.pt, c cast@ci.uc.pt, d a.b.horsfall@ncl.ac.uk, e kai.wang@ncl.ac.uk, f n.g.wright@ncl.ac.uk, g S.M.Soare@ncl.ac.uk, h s.j.bull@ncl.ac.uk, I Anthony.oneill@ncl.ac.uk, j Jon.Terry@ee.ed.ac.uk, k Anthony.Walton@ee.ed.ac.uk, l Alan.Gundlach@ee.ed.ac.uk, m Tom.Stevenson@ee.ed.ac.uk Keywords: Integrated circuits, metallization, aluminum, residual stresses, low-angle incidence Abstract.
Acknowledgements This work was supported by the Engineering and Physical Science Research Council, U.K. under Grant GR/N32945/01.
Forum, Vols. 347-349 (2000) p. 17-22

Introduction With the advanced of the ICT infrastructure, we are challenged with a huge quantity and diversity of documents in textual format to be processed.
As technological advances have accelerated in recent years, automatic classification tools for assisting patent engineers or decision-makers in patent analysis have been in great demand [10].
ACM SIGIR Forum archive.

Introduction In recent years, there have been increasing interests in developing bulk metallic glasses (BMGs) with great glass-forming ability (GFA) owing to the unique combination of properties, different from that of conventional materials and the potential engineering applications [1-9].
However, the engineering commercialization of these BMGs as structural materials is hindered by their limited GFA, low thermal stability and unsatisfactory manufacturability [9].
Nowosielski, Archives of Materials Science and Engineering, 38(1), (2009), p. 12 [6] H.J.
Schroers, Advanced Materials 22 (2010), p. 1566 [12] R.
Poulain , Materials Science Forum 19-20 (1987), p. 11 [14] Z.

Microstructure and Mechanical Properties of GMAW Welded Joints Er-Containing Aluminum Alloy Guo Haozhen1,a*, Cui Li1,b, Huang Hui1, Guo Xiao1, He Dingyong1 1The College of materials science and Engineering Beijing University of Technology, 100124, China a*649225523@qq.com, bcuili@bjut.edu.cn Keywords: Er-containing aluminum alloy; Gas metal arc welding; Mechanical properties Abstract.
Materials Science & Engineering A, 2004, 364(1):260-272
Development on re- search of advanced rear-earth aluminum alloy[J].
Materials Science Forum, 2002, 396-402(3):1731
Rare Metal Materials and Engineering, 2012, 41(1)

Li d Laboratory of Science and Technology on Advanced High Temperature Structural Materials, Beijing Institute of Aeronautical Materials, P.O.
Rare Metal materials and Engineering, 2017, 46(4): 912-916
Materials Science and Engineering A, 2004, 386(1-2): 129-139
Materials Science Forum, 2013, 747-748:535-539
Materials Science and Engineering, 1997, A237: 35-42.

Introduction In the modern mechanical engineering, various methods of wear-resistant coating with functional materials, including powder coating, ceramics and heat-resistant polymers, single and multicomponent metal and composite electroplated coatings, carbide coatings, etc. are widely used for surface hardening of agricultural machine parts made of structural alloyed steels [1].
Component content in the charge, wt. % Melting point HT, оС Thickness, mm Notes (quality characteristics) Alloy Flux 1. 88 12 1210-1220 1.7-2.0 Satisfactory 2. 87 13 1200-1210 1.5-2.0 3. 85 15 1190-1200 1.0-1.5 4. 92 8 1250-1270 2.0-2.5 Surfacing time is increased by 10-15 % 5. 90 10 1220-1250 2.5-2.7 6. 83 17 1180-1190 1.0-1.2 Low hardness 7. 81 19 1160-1180 1.0-1.2 Low hardness discontinuities Justification of selection of the materials and composition of the proposed new wear-resistant alloy for its subsequent induction deposition on the part to be hardened was based on modern theoretical concepts and advanced practical experience in new wear-resistant and surfacing materials obtaining.
Ishkov, Modification of wear-resistant coatings of Fe-Cr-C system based on the Cr3C2 obtained with help of SHS method, IOP Conference Series: Materials Science and Engineering. 441 (2018) 012047
Kishurov, Increasing the life of coated high-speed steel tools, Russian Engineering Research. 33(12) (2013) 727-730
Aulov, Improving the Characteristics of Wear-Resistant Coatings Obtained by HDTV-Boration, their Modification by Intermetallic Compounds of Fe-Al and Ni-Al Systems, Materials Science Forum. 992 (2020) 640-646.

Cheng: International Journal of Advanced Manufacturing Technology, Vol.20 (2002), pp.631-636
Wu: Materials Science Forum, Vol. 471-472 (2004), pp.663-667
Liu: Key Engineering Materials, Vol. 259-260 (2004), pp.462-465
Helander: Journal of Engineering Design, Vol. 13 (2002), pp.321-326
Li: Journal of Engineering Design,Vo1.13 (2002), pp.321-326.

Peng 1, e 1 Tribology Research Institute, Traction Power State Key Laboratory, Southwest Jiaotong University, Chengdu 610031, China 2 Sichuan Province Key Laboratory for Corrosion and Protection of Materials, Sichuan University of Science & Engineering, Zigong 643000, China a linxiuzhou@163.com, b zhuminhao@swjtu.cn, c czb-jiaoda@126.com, d tozhengjianfeng@126.com, e jinfangpeng3256@163.com Keywords: Micro-arc oxidation; Coating; Microstructure characterizations; Friction and wear; Reciprocating sliding; Al-Si alloy.
In this work, the MAO coating with lower cost have prepared on Al-Si alloy, the surface properties (including chemical state of elements in the MAO coatings) have characterized by many advanced surface analysis techniques, and the reciprocating sliding tribological behaviors have been investigated.
Tong: Materials Science & Engineering: A (Structural Materials: Properties, Microstructure and Processing) Vol. 476 (2008), p.78 [11] G.
Liu: Key Engineering Materials Vol. 315-316 (2006), p.259 [14] W.B.
Tian: Materials Science Forum Vol. 546-549 (2007), p. 1145 [15] K.

Cold Spray Metallization of Hybrid Thermoplastic - Thermoset Fiber Reinforced Composite Hetal Parmar1,a*, Roberta Della Gatta2,b, Antonio Viscusi2,c, Fausto Tucci1,d, Antonello Astarita2,e, Pierpaolo Carlone1,f 1Department of Industrial Engineering, University of Salerno, Italy 2Department of Chemical, Materials and Production Engineering, University of Naples Federico II, Italy ahparmar@unisa.it; broberta.dellagatta@unina.it, bantonio.viscusi@unina.it, dftucci@unisa.it, eantonello.astarita@unina.it, fpcarlone@unisa.it Keywords: Metallization; cold spray; polymer matrix composites; cocuring; resin infusion Abstract.
Introduction The key industry sectors are seeking out advanced materials and advanced manufacturing techniques to build high performances components [1,2,11–16,3–10].
Materials and Method The material selection for the experimental work was conducted from the advanced aerospace applications point of view.
Carlone, Advanced robotics and additive manufacturing of composites: towards a new era in Industry 4.0, Mater.
Forum Res.

Influence of Dissolved Precipitated Phases on Mechanical Properties of Severely Deformed Al-4 wt% Cu Alloys Nan Hu 1, a, Xiao-chang Xu 1, 2, b 1School of Materials Science and Engineering, Central South University, Changsha 410083, China 2Key Laboratory of Nonferrous Metal Materials Science and Engineering, Ministry of Education, Central South University, Changsha 410083, China asabinahu422@gmail.com, bxxc12@126.com, Keywords: Al-Cu alloy; severe plastic deformation; multi-axial compression; dissolution of precipitated phases; mechanical properties, annealing Abstract: Microstructural evolution and mechanical properties of Al-4.11 wt% Cu alloys subjected to multi-axial compression (MAC) and subsequent annealing were investigated.
Langdon: Materials Science and Engineering A Vol. 462 (2007), p. 3-11 [6] M.
Forum Vol. 396-402 (2002), p. 1163-1168 [8] X.C.
Srinivasan: Materials Science and Engineering: A Vol. 410-411 (2005), p. 394-397 [12] B.
Ma and Y.T Zhu: Advanced Materials Vol. 18 (2006), p. 2280–2283