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A Review on Water Footprint Research of Materials Industry Hualong Chen1,a, Yu Liu1,2,b*, Xianzheng Gong1,c, Liwei Hao3,d, Boxue Sun1,e, Xiaoqing Li1,f 1National Engineering Laboratory for Industrial Big-data Application Technology, Beijing 100124, China 2Beijing University of Technology, the Key Laboratory of Advanced Functional Materials, Ministry of Education of China, Beijing 100124, China 3Beijing Building Materials Academy of Sciences Research / State Key Laboratory of Solid Waste Reuse for Building Materials, Beijing 100041, China a2365993639@qq.com, b*liuyu@bjut.edu.cn, cgongxianzheng@bjut.edu.cn, dhlw717@126.com, esunboxue@bjut.edu.cn, flixiaoqing@bjut.edu.cn Keywords: Water footprint; Sustainable utilization; Research progress; Accounting methods Abstract.
Thirdly, the case studies on the water footprint of metallic materials, nonmetallic materials and chemical materials were reviewed to analyze its guidance significance on the sustainable development of water resources.
Water Footprint Application Research of Materials Products—Metallic Materials.
Water Footprint Application Research of Materials Products—Nonmetallic Materials.
Water Footprint Application Research of Materials Products—Chemical Materials.

Its material flow process is that, mining resources flow in the production process as raw materials, and then products made from raw materials access to trading market.
After purchased and used by consumers, waste materials changed from products are released to the environment, while those generated in the production are directly discharged to the environment[4].
This industry converts waste materials generated during production and utilization into reutilizing resources and products, including two processes, firstly, wastes are converted into renewable resources, then renewable resources are processed into products[5].
Jilin University Journal Social Sciences Edition, 2006(5): 43~45(in Chinese)
Journal of Guangxi Normal University (Philosophy and Social Sciences Edition) ,2009,45(3):33~37(in Chinese)

Experiment Materials and chemicals.All reagents were of analytical reagent grade unless otherwise specified.
It can be concluded that chelating agent EDDS can promote the adsorption of Cu2+ on three materials.
Effect of pH.The results on the Cu2+ removal with three materials are presented as a function of pH in Fig. 2.
Journal of Shenyang University of Chemical Technology 2010; 24:126-129
Chinese Journal of Environmental Engineering 2010; 4:2848-2852.

References [1] Kuzel, R., Janecek, M., Matej, Z., Cizek, J., Dopita, M., and Srba, O., Microstructure of Equal-Channel Angular Pressed Cu and Cu-Zr Samples Studied by Different Methods, Metallurgical and Materials Transactions A-Physical Metallurgy and Materials Science, 41(2010) 1174-1190
R., Multimodal Ultrafine Grain Size Distributions from Severe Plastic Deformation at High Strain Rates, Materials Science and Engineering a-Structural Materials Properties Microstructure and Processing, 527 (2009) 187-191
Thermal Modeling of the Metal Cutting Process - Part I - Temperature Rise Distribution Due to Shear Plane Heat Source, International Journal of Mechanical Sciences, 42 (2000) 1715-1752
J., and Hatherly, M., Recrystallization and Related Annealing Phenomena, Elsevier, New York 2004 [14] Ahlborn, H., Hornbogen, E., and Koster, U., Recrystallization Mechanism and Annealing Texture in Aluminum-Copper Alloys, Journal of Materials Science, 4 (1969) 944-950
P., Kapoor, R., and Suwas, S., Effect of Strain Rate on Evolution of the Deformation Microstructure and Texture in Polycrystalline Copper and Nickel, Metallurgical and Materials Transactions a-Physical Metallurgy and Materials Science, 41A (2010) 2794-2804.

Research on thermal character of Inorganic High Temperature Phase Change Materials Yue Feng Li1,2,a, Dong Zhang1*,b 1School of Materials Science and Engineering, Tongji University, Shanghai, China 2College of Science, Shanghai Institute of Technology, Shanghai, China aflywoud@gmail.com, bzhangdng@tongji.edu.cn(*Corresponding author) KeyWords: phase change material; energy storage; inorganic salt; thermal properties; high temperature.
Introduction Phase change materials (PCMs) are an energy storage materials that can store and release energy for different purposes.
Inorganic salt high temperature PCM is one of the solid-liquid phase change materials.
Experimental Materials.
Journal of Tongji University (Natural Science), 34(7) (2006) 928-932

Ma: Materials Science and Engineering R, Vol. 29 (2000), p. 49
Suryanarayana: Progress in Materials Science, Vol. 46 (2001), p. 1
Alexandrov: Progress in Materials Science, Vol. 45 (2000), p. 103
Langdon: Progress in Materials Science, Vol. 51 (2006), p. 881
Ringer: Journal of Materials Science, Vol. 42 (2007), p. 1551

Building materials constitute about 60%-70% of the total cost of construction.
Reduction in the use of conventional materials may not be possible; therefore, an alternative solution to use low cost materials would reduce the overall construction cost of a building.
Thus the alternative building materials which are to be replaced by the conventional materials should be made from waste or locally available materials to minimize environmental pollution and reduce overall construction cost [5] .
Khan, “Strength characteristics of low cost flyash brick masonry”, International Journal of Science, Environment and Technology, ISSN 2278-3687 (O) , Vol. 3, No 3 (2014) 976 – 980
Samer, “Towards the implementation of the Green Building concept in agricultural buildings”, a literature review CIGR Journal , Vol. 15, No.2 25, (July 2013) [12] Swetha madhusudanan, Lilly Rose amirtham, “Sustainable building materials and materials for energy efficiency “, Trans tech publications, ISBN-13:978-3-03835-490-1, periodical of Key engineering materials vol.650, (2015).

This periodical edition includes peer-reviewed papers based on results of scientific research and engineering solutions in different areas of modern engineering science.
Keywords:
Materials Science, Materials, Mechanics, Civil Engineering, Electrical Engineering, Cumputer Science, Environmental Engineering

Applied Sciences, 10, (2020) 7824
Journal of Materials Science and Engineering B. 5. (2015) 255-262. 10.17265/2161-6221/2015.7-8.001
Construction and Building Materials. 121. (2016) 338-353
Sustainable Materials and Technologies. 4. (2015) 1-17
Domone, Construction materials, Third Edition.

On Accurate Numerical Evaluation of Stress Intensity Factors and T-Stress in Functionally Graded Materials Jeong-Ho Kim 1,a and Glaucio H.
This paper revisits the interaction integral method to evaluate both the mixed-mode stress intensity factors and the T-stress in functionally graded materials under mechanical loading.
Tina Panontin), and the National Science Foundation (NSF) under grant CMS0115954 (Mechanics and Materials Program).
Kim: Mixed-mode crack propagation in functionally graded materials.
Dong: A novel application of the singular integral equation approach to evaluate T-stress in functionally graded materials.