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Online since: June 2022
Authors: Francesco Pietro Campo, Mario Grosso
For all the materials, the CR trend over time was also assessed, according to the Fick’s law.
Dotelli, Life cycle assessment of natural building materials: the role of carbonation, mixture components and transport in the environmental impacts of hempcrete blocks, Journal of Cleaner Production, Vol. 149, pp. 1051-1061, 2017
Yates, T., Characteristics of low-density hemp-lime building materials, Proceedings of Institution of Civil Engineers: Construction Materials, Vol. 165, issue 1, pp. 15-23, 2012
Ashraf, Carbonation of cement-based materials: Challenges and opportunities, Construction and Building Materials, Vol. 120, pp. 558-570, 2016
Olsen, et al., Global Carbon Budget 2020, Earth System Science Data, Vol. 12, issue 4, pp. 3269-3340, 2020.
Dotelli, Life cycle assessment of natural building materials: the role of carbonation, mixture components and transport in the environmental impacts of hempcrete blocks, Journal of Cleaner Production, Vol. 149, pp. 1051-1061, 2017
Yates, T., Characteristics of low-density hemp-lime building materials, Proceedings of Institution of Civil Engineers: Construction Materials, Vol. 165, issue 1, pp. 15-23, 2012
Ashraf, Carbonation of cement-based materials: Challenges and opportunities, Construction and Building Materials, Vol. 120, pp. 558-570, 2016
Olsen, et al., Global Carbon Budget 2020, Earth System Science Data, Vol. 12, issue 4, pp. 3269-3340, 2020.
Online since: October 2022
Authors: Qing Yun Ding, Xi Li, Chao Qun Ma, Peng Shen, Dan Ma, Yu Tang
Emily et Al. [6] prepared Ni/Al energetic materials by cold pressing nano-powders, and found that nano-powders were easier to ignite than energetic materials prepared by micron-sized powders.
References [1] ZHANG X F, ZHAO X N, Research progress of multifunctional energetic structural materials, Chinese Journal of Energetic Materials. 17(2009)731-739
[4] Ji C, He Y, Wang C T, Shock-induced reaction characteristics of an Al/Ni composite processed via accumulative roll-bonding, Materials Science Forum. 879(2017)2044-2049
Enhanced reactivity of Ni-Al reactive material formed by cold spraying combined with cold-pack rolling, Journal of Alloys and Compounds. 741(2018):883-894
[8] Bacciochini A, Bourdon-Lafleur S, Poupart C, Ni-Al Nanoscale Energetic Materials: Phenomena Involved During the Manufacturing of Bulk Samples by Cold Spray, Journal of Thermal Spray Technology. 23(2014)1142-1148
References [1] ZHANG X F, ZHAO X N, Research progress of multifunctional energetic structural materials, Chinese Journal of Energetic Materials. 17(2009)731-739
[4] Ji C, He Y, Wang C T, Shock-induced reaction characteristics of an Al/Ni composite processed via accumulative roll-bonding, Materials Science Forum. 879(2017)2044-2049
Enhanced reactivity of Ni-Al reactive material formed by cold spraying combined with cold-pack rolling, Journal of Alloys and Compounds. 741(2018):883-894
[8] Bacciochini A, Bourdon-Lafleur S, Poupart C, Ni-Al Nanoscale Energetic Materials: Phenomena Involved During the Manufacturing of Bulk Samples by Cold Spray, Journal of Thermal Spray Technology. 23(2014)1142-1148
Online since: February 2007
Authors: Jie Huang, H. B. Zhang, Mohan J. Edirisinghe
Electrohydrodynamic routes are relatively new for processing advanced materials and in this paper
we use electrospinning to prepare zirconia fibres diameter down to 200nm and hydroxyapatite (HA)
fibres down to 1µm.
Experimental Details (1) Materials PEO (molecular weight 2,000,000): PEG (molecular weight 8000) (1:2 weight ratio) was dissolved in a water-THF (Sigma-Aldrich) solution (10:1 by volume) using magnetic stirring over 24 hours.
McNeuer, Journal of Materials Science, Vol 19(1984), p. 3224
Bonfield, Journal of Materials Science, Materials in Medicine, Vol 15(2004), , p. 441
Dzenis, Science Vol 304(2004), p. 1917 [10] W.Sigmund, J.
Experimental Details (1) Materials PEO (molecular weight 2,000,000): PEG (molecular weight 8000) (1:2 weight ratio) was dissolved in a water-THF (Sigma-Aldrich) solution (10:1 by volume) using magnetic stirring over 24 hours.
McNeuer, Journal of Materials Science, Vol 19(1984), p. 3224
Bonfield, Journal of Materials Science, Materials in Medicine, Vol 15(2004), , p. 441
Dzenis, Science Vol 304(2004), p. 1917 [10] W.Sigmund, J.
Online since: August 2011
Authors: Pisutti Dararutana, Krit Won-In, Sorapong Pongkrapan
Refractive index is the important parameter for the transparent materials and largely depended on the density or specific gravity of the material.
At present, the local glass industry depends on the import of some raw materials.
Sirikulrat: KMITL Science Journal, Vol. 6 (2006), p. 541
Dararutana et al.: Advanced Materials Research, Vol. 39-40 (2008), p. 257
Hua et al.: Journal of Sol-Gel Science and Technology, Vol. 33 (2005), p. 169
At present, the local glass industry depends on the import of some raw materials.
Sirikulrat: KMITL Science Journal, Vol. 6 (2006), p. 541
Dararutana et al.: Advanced Materials Research, Vol. 39-40 (2008), p. 257
Hua et al.: Journal of Sol-Gel Science and Technology, Vol. 33 (2005), p. 169
Online since: August 2011
Authors: Wu Di Zhang, Fang Yin, Jian Chang Li, Rui Xu, Shi Qing Liu, Yu Bao Chen
There are three ways for methane biosynthesis: firstly, methane biosynthesis is based on acetic acid as raw materials; secondly, methane biosynthesis is based on hydrogen and carbon dioxide as raw materials; thirdly, methane biosynthesis is based on methyl compounds as raw materials.
Journal of Catastrophology, Vol.24 (2009), p. 63-67
Journal of Anhui Agricultural Science , Vol. 36 (2008), p.15658-15660
Environmental Science,Vol. 26(2005), p.172-173
Journal of Microbiology, Vol. 23(2003),p.42-46.
Journal of Catastrophology, Vol.24 (2009), p. 63-67
Journal of Anhui Agricultural Science , Vol. 36 (2008), p.15658-15660
Environmental Science,Vol. 26(2005), p.172-173
Journal of Microbiology, Vol. 23(2003),p.42-46.
Online since: November 2018
Authors: Jörg Kärger, Rustem Valiullin
Nanoporous materials find widespread application in material upgrading by separation (“molecular sieving”) and catalytic conversion.
Thus, also the term “nanoporous” materials has got into common use, as a more general, collective name for materials with pore sizes ranging from a few tenths of nm up to 100 nm [1] (see Fig. 1) Fig. 1: Nanoporous Materials (bottom) are key to petrol refineries and other plants for matter refining (top).
The problems with quantifying the various phenomena of relevance in nanoporous materials are intimately related with the complex structure of such materials.
Theodorou, Diffusion in Nanoporous Materials, Wiley - VCH, Weinheim, 2012
Kärger, Mesopore-Promoted Transport in Microporous Materials, Chem.
Thus, also the term “nanoporous” materials has got into common use, as a more general, collective name for materials with pore sizes ranging from a few tenths of nm up to 100 nm [1] (see Fig. 1) Fig. 1: Nanoporous Materials (bottom) are key to petrol refineries and other plants for matter refining (top).
The problems with quantifying the various phenomena of relevance in nanoporous materials are intimately related with the complex structure of such materials.
Theodorou, Diffusion in Nanoporous Materials, Wiley - VCH, Weinheim, 2012
Kärger, Mesopore-Promoted Transport in Microporous Materials, Chem.
Online since: October 2011
Authors: Fei Meng, Hai Ou Zhang, Gui Lan Wang, Xue Cheng Ping
In the DPST (Direct Prototype Spray Tooling) sprayed directly prototype tooling technology of Huazhong University of Science and Technology , due to brittle characteristics of ceramic materials, there was low efficient in the processing of large mold .The study would obtain sprayed ceramic prototypes through Industrial robots directly milling of ceramic rough technology, However, clay ceramic prototype embryos after milling would occur large shrinkage in the high-temperature drying and consolidation.
Introduction Due to ceramic materials was hard and brittle, this characteristics is much more difficult to machine than metal materials.
In this study, the ceramic materials of prototype used clay that it comes from Zhongxiang City, Hubei Province, China.
Acknowledgements This paper is supported by the national natural science fund project (51065008) and Jiangxi Province Education Department research project (GJJ11103).
[4] Li-Zhi Zhang,in: Coupled heat and mass transfer through asymmetric porous membranes with finger-like macrovoids structure, International Journal of Heat and Mass Transfer, 52 (2009),pp. 751–759
Introduction Due to ceramic materials was hard and brittle, this characteristics is much more difficult to machine than metal materials.
In this study, the ceramic materials of prototype used clay that it comes from Zhongxiang City, Hubei Province, China.
Acknowledgements This paper is supported by the national natural science fund project (51065008) and Jiangxi Province Education Department research project (GJJ11103).
[4] Li-Zhi Zhang,in: Coupled heat and mass transfer through asymmetric porous membranes with finger-like macrovoids structure, International Journal of Heat and Mass Transfer, 52 (2009),pp. 751–759
Online since: March 2014
Authors: Jiang Wen Liu, Yong Zhong Wu
Gupta: Journal of the Minerals, Metals and Materials Society (JOM) Vol. 58 (2006), p.71-76
Srikanth: Materials Science and Technology Vol. 26 (2010), p.289-296
Youming: Journal of Materials Science Vol.32 (1997), p.5545-5550
Taya: Journal of Materials Science Vol.24 (1989), p.1103-1108
Wan, et al: Journal of materials processing technology, Vol.102 (2000), p.90-102 [12] Z.D.
Srikanth: Materials Science and Technology Vol. 26 (2010), p.289-296
Youming: Journal of Materials Science Vol.32 (1997), p.5545-5550
Taya: Journal of Materials Science Vol.24 (1989), p.1103-1108
Wan, et al: Journal of materials processing technology, Vol.102 (2000), p.90-102 [12] Z.D.
Online since: June 2019
Authors: Vladimír Hrbek, Karel Šeps, Petr Bily, Josef Fladr, Roman Chylík
During production, an emphasis is given to the quality of raw materials, precision of dosing and homogenization procedure.
Despite detailed line indentation and microscopy, impact of supplementary cementitious materials on the thickness of the inter-facial transition zone was not conclusive.
Bolshakov, Understanding Nanoindentation Unloading Curves, Journal of Material Research 17 (2002), 2660 – 2671
Pharrr, Measuring of Hardness and Elastic Modulus by Instrumented Indentation: Advances in Understanding and Refinement of Methodology, Journal of Material Research 19 (2004), 3 – 20
Van Vliet, Grid Indentation Analysis of Composite Microstructure and Mechanics: Principles and Validation, Journal of Material Science and Engineering 430 (2006), 189 – 202
Despite detailed line indentation and microscopy, impact of supplementary cementitious materials on the thickness of the inter-facial transition zone was not conclusive.
Bolshakov, Understanding Nanoindentation Unloading Curves, Journal of Material Research 17 (2002), 2660 – 2671
Pharrr, Measuring of Hardness and Elastic Modulus by Instrumented Indentation: Advances in Understanding and Refinement of Methodology, Journal of Material Research 19 (2004), 3 – 20
Van Vliet, Grid Indentation Analysis of Composite Microstructure and Mechanics: Principles and Validation, Journal of Material Science and Engineering 430 (2006), 189 – 202
Online since: August 2009
Authors: Ambika Sharma, P.B. Barman
Introduction
In contrast to amorphous silicon and other group-IV tetrahedrally bonded semiconductors, the
chalcogenide glasses have a Kerr non-linearity a hundred times larger than that of silica [1], making
them excellent and unique materials for the fabrication of devices for integrated and fiber optics.
The values of R are found to be greater than unity for glasses with chalcogen-rich materials, and less than unity for glasses with chalcogen-poor materials.
References [1] I.Sharma, S.K.Tripathi, A.Monga and P.B.Barman: Journal of Non-Crystalline Solids, 2008, 354, 3215 [2] M.Frumar and T.Wagner: Current Opinion in Solid State Materials Science, 2003, 7, 117 [3] A.Znobrik, J.Stetzif, I.Kavich, V.Kavich, V.Osipenko, I.Zachko, N.Balota and O.Jakivchuk: Ukrainian Physics Journal, 1981, 26, 212 [4] J.S.Sanghera and I.D.Aggarwal: Journal of Non-Crystalline Solids, 1999, 256-257, 6 [5] K.Schwartz: The Physics of Optical Recording (Berlin:Springer) (1993) [6] A.Bradley: Optical Storage for Computers Technology and Applications (New York: Ellis Harwood Limited) (1989) [7] J.Bradangna and S.A.Keneman: Holographic Recording Media, Ed.
Mater., 2002, 4, 729 [10] J.Troles, F.Smektala, G.Boudebsa, A.Monteila, B.Bureau and J.Lucas: Applied Physics Letters, 1986, 49, 22 [11] T.Takamori, R.Roy, G.J.Mccarthy: Materials Research Bulletin, 1970, 5, 529 [12] S.Lizima, M.Suzi, M.Kikuchi, K.Tanaka: Solid State Communications, 1970, 8, 153 [13] J.A.Savaga: Journa; of Materials Science, 1971, 6, 964 [14] J.A.Savaga: Journal of Non-Crystalline Solids, 1972, 11 121 [15] S.Bordas, Vazquez J.Casas, N.Clavaguera, Mora M.T.Clavaguera: Thermochimica Acta, 1973, 28 387 [16] K.Fukui: Journal of the Physical Society of Japan, 1992, 61 1084 [17] I.Kaban, T.Halm, W.Hoyer, P.Jovari, J.Neuefeind: Journal of Non-Crystalline Solids, 2003, 326-327, 120 [18] A.K.Varshneya, D.J.Mauro: Journal of Non-Crystalline Solids, 2007, 353, 1291 [19] M.Micoulaut, J.C.Phillips: Physical Review B, 2003, 67, 104204 [20] P.Boolchand, X.Feng, W.J.Bresser: Journal of Non-Crystalline Solids, 2001, 293-295, 348 [21] S.A.Fayek, M.R.Balboul,
(Cornell University Press, Ihica NY), 1960 [23] L.Zhenhua: Journal of Non-Crystalline Solids, 1981, 127, 298 [24] S.O.Kasap and S.Yannacopoulos: Journal of Materials Research, 1989, 4, 893 [25] L.Tichy, H.Ticha: Materials Letters, 1994, 21, 313 [26] L.Tichy, H.Ticha: Journal of Non-Crystalline Solids, 1995, 189, 141 [27] A.K.Pattanaik and A.Srinivasan: J.
The values of R are found to be greater than unity for glasses with chalcogen-rich materials, and less than unity for glasses with chalcogen-poor materials.
References [1] I.Sharma, S.K.Tripathi, A.Monga and P.B.Barman: Journal of Non-Crystalline Solids, 2008, 354, 3215 [2] M.Frumar and T.Wagner: Current Opinion in Solid State Materials Science, 2003, 7, 117 [3] A.Znobrik, J.Stetzif, I.Kavich, V.Kavich, V.Osipenko, I.Zachko, N.Balota and O.Jakivchuk: Ukrainian Physics Journal, 1981, 26, 212 [4] J.S.Sanghera and I.D.Aggarwal: Journal of Non-Crystalline Solids, 1999, 256-257, 6 [5] K.Schwartz: The Physics of Optical Recording (Berlin:Springer) (1993) [6] A.Bradley: Optical Storage for Computers Technology and Applications (New York: Ellis Harwood Limited) (1989) [7] J.Bradangna and S.A.Keneman: Holographic Recording Media, Ed.
Mater., 2002, 4, 729 [10] J.Troles, F.Smektala, G.Boudebsa, A.Monteila, B.Bureau and J.Lucas: Applied Physics Letters, 1986, 49, 22 [11] T.Takamori, R.Roy, G.J.Mccarthy: Materials Research Bulletin, 1970, 5, 529 [12] S.Lizima, M.Suzi, M.Kikuchi, K.Tanaka: Solid State Communications, 1970, 8, 153 [13] J.A.Savaga: Journa; of Materials Science, 1971, 6, 964 [14] J.A.Savaga: Journal of Non-Crystalline Solids, 1972, 11 121 [15] S.Bordas, Vazquez J.Casas, N.Clavaguera, Mora M.T.Clavaguera: Thermochimica Acta, 1973, 28 387 [16] K.Fukui: Journal of the Physical Society of Japan, 1992, 61 1084 [17] I.Kaban, T.Halm, W.Hoyer, P.Jovari, J.Neuefeind: Journal of Non-Crystalline Solids, 2003, 326-327, 120 [18] A.K.Varshneya, D.J.Mauro: Journal of Non-Crystalline Solids, 2007, 353, 1291 [19] M.Micoulaut, J.C.Phillips: Physical Review B, 2003, 67, 104204 [20] P.Boolchand, X.Feng, W.J.Bresser: Journal of Non-Crystalline Solids, 2001, 293-295, 348 [21] S.A.Fayek, M.R.Balboul,
(Cornell University Press, Ihica NY), 1960 [23] L.Zhenhua: Journal of Non-Crystalline Solids, 1981, 127, 298 [24] S.O.Kasap and S.Yannacopoulos: Journal of Materials Research, 1989, 4, 893 [25] L.Tichy, H.Ticha: Materials Letters, 1994, 21, 313 [26] L.Tichy, H.Ticha: Journal of Non-Crystalline Solids, 1995, 189, 141 [27] A.K.Pattanaik and A.Srinivasan: J.