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Online since: November 2025
Authors: Olexandr Alexandrov, Mykyta Alexandrov, Yuriy Sychov, Mykola Riabchykov
This enables the creation of materials with controlled permeability.
Further research in this field remains highly relevant, particularly in connection with the development of energy-efficient construction and materials science.
Jian, Transient determination of water vapor diffusion coefficient of porous building materials, Journal of Zhejiang University (Engineering Science), 50 1 (2016) 16-20, ISSN 1008-973X, https://doi.org/10.3785/j.issn.1008-973X.2016.01.003
Qu, Experimental determination on the capillary water absorption coefficient of porous building materials: A comparison between the intermittent and continuous absorption tests, Journal of Building Engineering, Volume 28 (2020) 101091, https://doi.org/10.1016/j.jobe.2019.101091
Materials, 17(19) (2024) 4903. https://doi.org/10.3390/ma17194903
Further research in this field remains highly relevant, particularly in connection with the development of energy-efficient construction and materials science.
Jian, Transient determination of water vapor diffusion coefficient of porous building materials, Journal of Zhejiang University (Engineering Science), 50 1 (2016) 16-20, ISSN 1008-973X, https://doi.org/10.3785/j.issn.1008-973X.2016.01.003
Qu, Experimental determination on the capillary water absorption coefficient of porous building materials: A comparison between the intermittent and continuous absorption tests, Journal of Building Engineering, Volume 28 (2020) 101091, https://doi.org/10.1016/j.jobe.2019.101091
Materials, 17(19) (2024) 4903. https://doi.org/10.3390/ma17194903
Online since: May 2011
Authors: Shi Qun Guo, Zhen Yang
Fundamental solutions of a normal force in semi-infinite coating materials.
In common, main failure of coating materials is delamination.
Nix: Journal of Materials Research, Vol. 14(1999): p. 2196-2203 [3] T.Y.
Nix: Journal of Materials Research, Vol. 14(1999): p. 2204-2209 [4] H.
Fischer-Cripps: Journal of Materials Science, Vol. 32(1997): p. 5653-5659 [6] J.F.
In common, main failure of coating materials is delamination.
Nix: Journal of Materials Research, Vol. 14(1999): p. 2196-2203 [3] T.Y.
Nix: Journal of Materials Research, Vol. 14(1999): p. 2204-2209 [4] H.
Fischer-Cripps: Journal of Materials Science, Vol. 32(1997): p. 5653-5659 [6] J.F.
Online since: October 2014
Authors: Zi Yi Yang, Jing Gui Wu, Chuang Chen, Na Na Feng
Three kinds of organic materials were used for culture experiment, namely livestock manures, natural organic materials and half decomposed organic materials.
The amplifications of livestock manures and natural organic materials are higher then half decomposed organic materials.
Materials and Methods Experiment design.
Different organic materials played different roles on morphologic transformation of Mn, fertilizers only led the fractions of Mn transform from low bio-availability to high bio-availability, which called active transformation[[] Sun H, Tan C Y, Huang D Y: Journal of Natural Science of Hunan Normal University. vol.34 (2011), p.82. ].
Different kinds of organic materials all increased the total Mn contents, Xie Z L explained that the total heavy metal contents was determined by the entrance and export of Cu and Zn in soil [[] Xie Z L, Zhu H S, Li W Y: Journal of Agro-Environment Science.
The amplifications of livestock manures and natural organic materials are higher then half decomposed organic materials.
Materials and Methods Experiment design.
Different organic materials played different roles on morphologic transformation of Mn, fertilizers only led the fractions of Mn transform from low bio-availability to high bio-availability, which called active transformation[[] Sun H, Tan C Y, Huang D Y: Journal of Natural Science of Hunan Normal University. vol.34 (2011), p.82. ].
Different kinds of organic materials all increased the total Mn contents, Xie Z L explained that the total heavy metal contents was determined by the entrance and export of Cu and Zn in soil [[] Xie Z L, Zhu H S, Li W Y: Journal of Agro-Environment Science.
Online since: March 2011
Authors: Javier Signorelli, Mariano Serenelli, María Bertinetti, Pablo Turner
By referring to previous FLD studies based on the FC-Taylor model ─ Wu and coworkers [Effect of an initial cube texture on sheet metal formability, Materials Science and Engineering A, 364:182–7, 2004] and Inal and coworkers [Forming Limit comparison for FCC and BCC sheets, International Journal of Plasticity, 21:1255-1266, 2005] ─ we found that the MK-FC strategy leads to unrealistic results.
Aboutajeddine; International Journal of Plasticity, 21:1255-1266, 2005) Inal et al. [8] performed numerical simulations of FLDs using 12 and 24 slip systems for FCC and BCC materials, respectively.
In this work, we apply our model for predicting FLDs to both FCC and BCC materials.
Stress potential at equi-biaxial failure for all tested materials.
Neale; Materials Science and Engineering A, 364:182-7, 2004) Wu and co-workers performed a detailed study of the influence of the cube orientations on a FCC material formability.
Aboutajeddine; International Journal of Plasticity, 21:1255-1266, 2005) Inal et al. [8] performed numerical simulations of FLDs using 12 and 24 slip systems for FCC and BCC materials, respectively.
In this work, we apply our model for predicting FLDs to both FCC and BCC materials.
Stress potential at equi-biaxial failure for all tested materials.
Neale; Materials Science and Engineering A, 364:182-7, 2004) Wu and co-workers performed a detailed study of the influence of the cube orientations on a FCC material formability.
Online since: February 2014
Authors: Nikol Žižková, Jitka Hroudová, Jiří Zach
Insulation materials based on natural fibers represent a good alternative for current standardly used insulation materials like foamed plastic materials and mineral wool.
Input materials for such industrial insulation materials are particularly crude oil and non-renewable natural resources (moreover, manufacture of these insulation materials consumes high amount of energy).
To compare behavior of thermo insulating materials in the ETICS system, classic thermo-insulating materials were used (EPS, Multipor) as well as alternative materials - hemp boards, flax boards, straw boards.
Indian Journal of Fibre & Textile Research [online], Vol. 34, p. 377 – 379. (2009).
Journal of Sol-gel Science and Technology [online], Vol. 58, Issue 1, p. 18-23. (2011) Information on: http://link.springer.com/article/10.1007%2Fs10971-010-2349-8?
Input materials for such industrial insulation materials are particularly crude oil and non-renewable natural resources (moreover, manufacture of these insulation materials consumes high amount of energy).
To compare behavior of thermo insulating materials in the ETICS system, classic thermo-insulating materials were used (EPS, Multipor) as well as alternative materials - hemp boards, flax boards, straw boards.
Indian Journal of Fibre & Textile Research [online], Vol. 34, p. 377 – 379. (2009).
Journal of Sol-gel Science and Technology [online], Vol. 58, Issue 1, p. 18-23. (2011) Information on: http://link.springer.com/article/10.1007%2Fs10971-010-2349-8?
Online since: August 2009
Authors: Si Rong Zhu, Xiao Yu Zhang, Zhuo Qiu Li, Ya Wen Dai
Virtual Experimental Studies on
Carbon Fiber Smart Materials Resistivity Tomography
Yawen Daia, Zhuoqiu Lib, Xiaoyu Zhang, Sirong Zhu
School of Science, Wuhan University of Technology, Wuhan,China
a
daiyaweny@163.com, bscience@whut.edu.cn
Keywords: carbon fiber smart materials,virtual experiment,resistivity tomography, field monitoring.
Introduction With development of smart materials and sensor technology, it is possible to diagnose and supervise security service characteristics of critical civil engineering [1].
With conductivity and piezoresistivity of smart materials and resistivity tomography, it is hopeful to realize visible field monitoring on civil engineering structure.
Acknowledgement The work was supported by the National Natural Science Foundation of China (No. 50878169).
Chung, Carbon Fiber-Reinforced Cement as a Strain-Sensing Coating, Cement and Concrete Research, 2001, 31:665-667 [4] Zhang Xiaoyu, Li Zhuoqiu, Song Xianhui, Zhu Sirong, Manufacture and Characteristics of Cement-Based Smart Surface, Huazhong University of Science and Technology Journal (natural science edition), 2006, 34(8): 97-99 [5] Zhang Xiaoyu, Li Zhuoqiu, Song Xianhui, Study on Sensing Feature of Carbon Fiber Smart Layer, Huazhong University of Science and Technology Journal 2008, 25(2): 36-38 [6] Mei Shuhui, Array Simulation on Carbon Fiber Smart Layer and its Structure [D], Wuhan University of Technology Master Paper, 2007.5
Introduction With development of smart materials and sensor technology, it is possible to diagnose and supervise security service characteristics of critical civil engineering [1].
With conductivity and piezoresistivity of smart materials and resistivity tomography, it is hopeful to realize visible field monitoring on civil engineering structure.
Acknowledgement The work was supported by the National Natural Science Foundation of China (No. 50878169).
Chung, Carbon Fiber-Reinforced Cement as a Strain-Sensing Coating, Cement and Concrete Research, 2001, 31:665-667 [4] Zhang Xiaoyu, Li Zhuoqiu, Song Xianhui, Zhu Sirong, Manufacture and Characteristics of Cement-Based Smart Surface, Huazhong University of Science and Technology Journal (natural science edition), 2006, 34(8): 97-99 [5] Zhang Xiaoyu, Li Zhuoqiu, Song Xianhui, Study on Sensing Feature of Carbon Fiber Smart Layer, Huazhong University of Science and Technology Journal 2008, 25(2): 36-38 [6] Mei Shuhui, Array Simulation on Carbon Fiber Smart Layer and its Structure [D], Wuhan University of Technology Master Paper, 2007.5
Online since: March 2016
Authors: Shi Zhao Wang, Zhong Ji, Pei Yao Sheng
2D Meso-Scale Finite Element Modeling and Simulation of
Polymer-Mineral Composite Material
Peiyao Sheng, Shizhao Wang and Zhong Ji*
Key Laboratory for Liquid–Solid Structural Evolution and Processing of Materials (MOE),
School of Materials Science and Engineering, Shandong University,
17923 Jingshi Road, Jinan, China 250061
jizhong@sdu.edu.cn
Keywords: Mineral composite material, Meso-scale model, Numerical analysis.
By comparing the materials’ properties under four different gradations, it can be found that the materials with SAC gradation have the best mechanical property.
Mao, et al, Numerical analysis on failure behaviour of polyurethane polymer concrete at high strain rates in compression, Computational Materials Science. 69(2013) 389-395
I: numerical model and tensile behavior, Materials and Structures. 41(2008) 583–99
Liu, Monte Carlo simulation of complex cohesive fracture in random heterogeneous quasi-brittle materials: a 3D study, International Journal of Solids and Structures. 47 (2010) 2336–45
By comparing the materials’ properties under four different gradations, it can be found that the materials with SAC gradation have the best mechanical property.
Mao, et al, Numerical analysis on failure behaviour of polyurethane polymer concrete at high strain rates in compression, Computational Materials Science. 69(2013) 389-395
I: numerical model and tensile behavior, Materials and Structures. 41(2008) 583–99
Liu, Monte Carlo simulation of complex cohesive fracture in random heterogeneous quasi-brittle materials: a 3D study, International Journal of Solids and Structures. 47 (2010) 2336–45
Online since: July 2020
Authors: Saif M. Abbas, Muhammed Abdul Sattar, Ghanim Sh. Sadiq
Improving the Composite Materials for Bi Lateral Prosthesis with Below Knee Amputation
Saif M.
Experimental Materials.
Series: Materials Science and Engineering 433 (2018)
Series: Materials Science and Engineering 454 (2018)
Series: Materials Science and Engineering 4671 (2020)
Experimental Materials.
Series: Materials Science and Engineering 433 (2018)
Series: Materials Science and Engineering 454 (2018)
Series: Materials Science and Engineering 4671 (2020)
Online since: August 2011
Authors: Pei Hao Lin, Shun Kang Pan, Hua Mei Wan, Lei Wang
References
[1] J.H.Liu, T.Y.Ma, H.Tong, W.Luo, M.Yan: Journal of Magnetism and Magnetic Materials.
[2] G.Z.Xie, P.Wang, B.S.Zhang, L.K.Yuan, Y.Shi, P.H.Lin, H.X Lu: Journal of Magnetism and Magnetic Materials.
[3] U.R.Lima, M.C.Nasar, R.S.Nasar, M.C.Rezende, J.H.Araújo: Journal of Magnetism and Magnetic Materials.
[7] V.Petrov, V.V.Gagulin: Inorganic Materials.
(in Chinese) [11] S.S.Kim, S.T.Kim, J.M.Ahn, K.H.Kim: Journal of Magnetism and Magnetic Materials.
[2] G.Z.Xie, P.Wang, B.S.Zhang, L.K.Yuan, Y.Shi, P.H.Lin, H.X Lu: Journal of Magnetism and Magnetic Materials.
[3] U.R.Lima, M.C.Nasar, R.S.Nasar, M.C.Rezende, J.H.Araújo: Journal of Magnetism and Magnetic Materials.
[7] V.Petrov, V.V.Gagulin: Inorganic Materials.
(in Chinese) [11] S.S.Kim, S.T.Kim, J.M.Ahn, K.H.Kim: Journal of Magnetism and Magnetic Materials.