Materials Engineering. Flextronics shall perform, on an ongoing basis, all activities necessary to provide continuity of supply of Products in accordance with the terms of this Agreement, such activities to include, but not be limited, to the following:
(a) conduct strategic technical analysis of the supply base to proactively warn of potential trouble areas with respect to End-of-Life Inventory by product family;
(b) monitor all aspects of Product and Material life cycle;
(c) apply necessary material engineering resource to provide material qualification;
(d) qualify any source of supply managed by Fxxxxxxxxxx, pursuant to Section 4.4.3(c);
(e) review and recommend material substitution opportunities;
(f) monitor and resolve Material performance to Specification issues; and
(g) drive and enhance Tier 2 Supplier’s Material quality and performance.
Materials Engineering. Advanced materials development: performance enhancement, modelling, la-srgcaele preparation, modification, tailoring, optimisation, novel and combined use of materials, etc.
1.11.1 Engineering of biomaterials, biomimetic, bioinspired and b-ieonabled materials
1.11.2 Engineering of metals and alloys
1.11.3 Engineering of ceramics and glasses
1.11.4 Engineering of polymers and plastics
1.11.5 Engineering of composites and hybrid materials
1.11.6 Engineering of carbon materials
1.11.7 Engineering of metal oxides
1.11.8 Engineering of alternative established or emergent materials
1.11.9 Nanomaterials engineering, e.g. nanoparticles, nanoposromuaterials, 1D & 2D nanomaterials
Materials Engineering. Materials Engineering involves engineering of materials themselves; materials are designed and selected for their function in society. Materials Engineering students will learn to think in the materials paradigm, which focuses on the interrelationships between structure, properties, processing, and performance. Materials Engineers also characterize the structure, properties, and performance of materials in order to determine interrelationships. Students who want to take Materials Engineering will benefit by developing spatial reasoning skills, the ability to visualize technical information, and an interest in small length scales and how materials fail. Materials Engineering involves selecting the length scale of the material (from molecular or atomic, to nano, micro and macro) and by choosing the class of material (from soft to hard to composites) while integrating this knowledge through the processing, structure, properties and performance of materials. The discipline focuses on the production and engineering applications of metallic and non-metallic materials (polymers, ceramics, composites, electronic materials and biomaterials). Materials Engineers develop, modify, and use processes to convert raw materials to useful engineering materials with specified desirable properties. The discipline therefore includes aspects of materials production, materials processing, materials applications, and design. Materials Engineering embraces physics, chemistry and mechanics to understand processing and applications of materials. Graduates of the program find employment in all sectors of the materials cycle. The primary sector is raw materials processing and includes such industries as mineral processing, aluminium smelting and steel making. The next sector is manufacturing and extends from the rolling of the metals to the materials engineering aspects of manufacturing products in the aerospace, automotive, electronics, photonics, and petrochemical industries. The final sector includes the service industries with such specialities as corrosion, wear, fracture mechanics and failure investigation. This sector also includes the recycling industries. In all sectors Materials Engineers are often involved with the selection of materials for use in designs, and are consulted for failure analysis. The undergraduate Materials Engineering program, the only one of its kind in the prairie provinces, includes a set of core materials engineering courses emphasizing underlying prin...
