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Online since: June 2014
Authors: Han Jun Wu, Shu Hang Jiang, Zhi Quan Pan, Hua Li Zhang
However, the research more of that are amino-modified mesoporous materials, amino-modified resin and amino-modified activated carbon, studies about CO2 adsorption by natural mineral materials were not reported.
The structure, thermal property, and pore size distribution of materials in different stages were characterized by XRD, FT-IR, TG/DSC, BET, and the CO2 adsorption capacity of the modified material were determined by gravimetric analyzer.
Progress in Polymer Science, 2009, 34(6):561-580
Journal of Materials Science and Engineering, 2007, 25(2): 307-312
CIESC Journal, 2008, 59(9): 2329-2333
The structure, thermal property, and pore size distribution of materials in different stages were characterized by XRD, FT-IR, TG/DSC, BET, and the CO2 adsorption capacity of the modified material were determined by gravimetric analyzer.
Progress in Polymer Science, 2009, 34(6):561-580
Journal of Materials Science and Engineering, 2007, 25(2): 307-312
CIESC Journal, 2008, 59(9): 2329-2333
Numerical Analysis of a Steel Frame Building with Soft-Storey Failure under Ground Motion Excitation
Online since: November 2012
Authors: Robert Jankowski, Wojciech Migda
It may further lead to progressive collapse of the whole structure substantially intensifying human losses and material damages.
If the progressive collapse is initiated, human as well as material losses are significantly intensified.
Jankowski: Journal of Applied Sciences Vol. 8 (2008), p.1850
Jankowski: Key Engineering Materials Vol. 417-418 (2010), p. 513
Jankowski: Journal of Applied Sciences Vol. 12 (2012), p. 466.
If the progressive collapse is initiated, human as well as material losses are significantly intensified.
Jankowski: Journal of Applied Sciences Vol. 8 (2008), p.1850
Jankowski: Key Engineering Materials Vol. 417-418 (2010), p. 513
Jankowski: Journal of Applied Sciences Vol. 12 (2012), p. 466.
Online since: August 2013
Authors: Pei Fang Su, Xing Li Lu
References
[1] C Liu: J. of Materials in Civil Engineering (ASCE). 2004, 16(5): 427-432
(inChinese) [7] G.De Schutter, L.Taerwe: Materials and Structures, Vol. 29, July 1996, pp 335-344
Taerwe: Materials and Structures Vol. 33, July 2000, pp 370-380
Bjantegaard, E.J.Sellevold: Materials and Structures, Vol..36, May 2003, pp 218-225
,Tank,R.C: ACI Materials Journal, Vol.89, No.2, 1992: 188-196
(inChinese) [7] G.De Schutter, L.Taerwe: Materials and Structures, Vol. 29, July 1996, pp 335-344
Taerwe: Materials and Structures Vol. 33, July 2000, pp 370-380
Bjantegaard, E.J.Sellevold: Materials and Structures, Vol..36, May 2003, pp 218-225
,Tank,R.C: ACI Materials Journal, Vol.89, No.2, 1992: 188-196
Online since: January 2015
Authors: M.A. Vysotskaya, Аlex Korotkov
Introduction
Today, the most widespread type of organic knitting materials is oil bitumen.
Due to the limitation of stocks of oil raw materials and big needs of road construction for organic knitting materials special relevance is gained by expansion of resources for their receiving at the expense of use of various waste of the industry, and also development of technologies of receiving economic and eco-friendly organic knitting and road-building materials on their basis.
One of the effective directions in the road materials science, allowing in a complex to approach to the solution of actual problems of branch such as: resource-and energy saving, technological effectiveness and environmental friendliness of production, and also extension of a construction season with improvement of quality of pavings is development and deployment of emulsion technologies.
In work stone materials were used: the main – marble and sour – granite.
Emulsion Science.
Due to the limitation of stocks of oil raw materials and big needs of road construction for organic knitting materials special relevance is gained by expansion of resources for their receiving at the expense of use of various waste of the industry, and also development of technologies of receiving economic and eco-friendly organic knitting and road-building materials on their basis.
One of the effective directions in the road materials science, allowing in a complex to approach to the solution of actual problems of branch such as: resource-and energy saving, technological effectiveness and environmental friendliness of production, and also extension of a construction season with improvement of quality of pavings is development and deployment of emulsion technologies.
In work stone materials were used: the main – marble and sour – granite.
Emulsion Science.
Online since: May 2020
Authors: Ragil Darmawan, Adolf Leopold S.M. Sihombing
The calorific value of waste materials is influenced by water content, oxygen, and hydrogen content.
This value is still higher than international standards for RDF raw materials in several countries as in Table 4.
It is assumed that after 2031 there will be no addition of raw materials for waste so electricity production has decreased.
Based on this technical calculation, incineration gives the most value of power generation and can reduce the most of waste materials.
American Journal of Environmental Science 8 (3) page: 291-296.
This value is still higher than international standards for RDF raw materials in several countries as in Table 4.
It is assumed that after 2031 there will be no addition of raw materials for waste so electricity production has decreased.
Based on this technical calculation, incineration gives the most value of power generation and can reduce the most of waste materials.
American Journal of Environmental Science 8 (3) page: 291-296.
Online since: October 2017
Authors: Wan Hairul Anuar Kamaruddin, Md Supar Rohani, K.Z. Hashim
Six phases that needed to form a single crystal using CZ technique are; preparation of materials, seeding, core growth, main growth, and lastly the separation of crystals from melt and cooling [6].
Acknowledgement The authors gratefully acknowledge the financial support from MOHE, MyBrain15 and UTM under vote 4F897 and the technical support of Faculty of Science, UTM.
Optical Properties of Reduced LiNbO3, Journal Phys.
Growth and properties of Ru-doped lithium niobate crystal, Journal of Crystal Growth, Vol 294(2), (pp. 323–329)
Stoichiometric LiNbO3 single crystal growth by double crucible Czochralski method using automatic powder supply system, Journal of Crystal Growth, Vol 116(3–4), (pp. 327-332)
Acknowledgement The authors gratefully acknowledge the financial support from MOHE, MyBrain15 and UTM under vote 4F897 and the technical support of Faculty of Science, UTM.
Optical Properties of Reduced LiNbO3, Journal Phys.
Growth and properties of Ru-doped lithium niobate crystal, Journal of Crystal Growth, Vol 294(2), (pp. 323–329)
Stoichiometric LiNbO3 single crystal growth by double crucible Czochralski method using automatic powder supply system, Journal of Crystal Growth, Vol 116(3–4), (pp. 327-332)
Online since: May 2020
Authors: Hui Huang, Yu Sheng Ding, Sheng Ping Wen, Xiao Lan Wu, Zuo-Ren Nie, Kun Yuan Gao, Pei Hao Zhao
Materials Science & Engineering A (Structural Materials: Properties, Microstructure and Processing) 391.1-2 (2005) 367-376
Journal of Materials Science & Technology 32.7 (2016) 660-670
Journal of Materials Science 46.4 (2011) 875-881
Metallurgical & Materials Transactions A 40.3 (2009) 717-728
Materials Science & Engineering A (Structural Materials:, Properties, Microstructure and Processing) 244.2 (1998) 257-262
Journal of Materials Science & Technology 32.7 (2016) 660-670
Journal of Materials Science 46.4 (2011) 875-881
Metallurgical & Materials Transactions A 40.3 (2009) 717-728
Materials Science & Engineering A (Structural Materials:, Properties, Microstructure and Processing) 244.2 (1998) 257-262
Online since: December 2010
Authors: Hideo Nakae, Yuji Kato, Ying Zou
Two groups of parent alloys were
prepared using high purity materials, i.e., Group 1 containing the spheroidizing element of Ce, Mg or
Ca, while in Group 2, S was added as an anti-spheroidizing element.
References [1] H.Morrogh and J.W.Grant: Foundry Trade Journal, Jul. (1948), p. 27 [2] H.Morrogh and W.J.Williams: J.Iron Steel Inst., Vol. 158 (1948), p. 306 [3] A.P.Gagnebin, K.D.Millis and N.B.Pilling: The Iron Age, Feb. (1949), p. 77 [4] A.P.Gagnebin, K.D.Millis and N.B.Pilling: The Iron Age, Feb. (1949), p. 97 [5] B.Lux: AFS Cast Metals Res.
Journal, (1972), p. 25 [6] B.Lux: AFS Cast Metals Res.
Journal, (1972), p. 49 [7] W.W.Braidwood and A.D.Busby: Foundry Trade Journal, (1949), p. 327 [8] J.E.Hurst, D.Met., F.I.M. and R.V.Riley: Foundry Trade Journal, (1949), p. 393 [9] G.Vennerholm, H.Bogart, and R.Melmoth: Foundry Trade Journal, (1950), p. 247 [10] S.H.Jung, T.Ishikawa and H.Nakae: Materials Sci. and Eng.
A, Vol. 476 (2008), p. 350 [11] H.Nakae and H.Shin: Proc. of the International Conference on the Science of Casting and Solidification, (2001), p. 336 [12] Morrogh and W.J.Williams: J.Iron Steel Inst., Vol. 155 (1947), p. 321 [13] Y.Tatsuzawa, S.Jung and H.Nakae: International Journal of Cast Metals Research, Vol. 21 (2008), p. 17 [14] Y.Tatsuzawa and H.Nakae: Journal of Japan Foundry Engineering Society, Vol. 82 (2010), p. 212-217 [15] N.Matsumoto, T.Misawa, S.Kubo and T.Ototani: The 1566th Report of the Research Institute for Iron, Steel and Other Metals, 1973, p. 87-96 [16] J.Park and S.Kim: Graphite Spherulites, Vol. 36 (1997), p. 1403
References [1] H.Morrogh and J.W.Grant: Foundry Trade Journal, Jul. (1948), p. 27 [2] H.Morrogh and W.J.Williams: J.Iron Steel Inst., Vol. 158 (1948), p. 306 [3] A.P.Gagnebin, K.D.Millis and N.B.Pilling: The Iron Age, Feb. (1949), p. 77 [4] A.P.Gagnebin, K.D.Millis and N.B.Pilling: The Iron Age, Feb. (1949), p. 97 [5] B.Lux: AFS Cast Metals Res.
Journal, (1972), p. 25 [6] B.Lux: AFS Cast Metals Res.
Journal, (1972), p. 49 [7] W.W.Braidwood and A.D.Busby: Foundry Trade Journal, (1949), p. 327 [8] J.E.Hurst, D.Met., F.I.M. and R.V.Riley: Foundry Trade Journal, (1949), p. 393 [9] G.Vennerholm, H.Bogart, and R.Melmoth: Foundry Trade Journal, (1950), p. 247 [10] S.H.Jung, T.Ishikawa and H.Nakae: Materials Sci. and Eng.
A, Vol. 476 (2008), p. 350 [11] H.Nakae and H.Shin: Proc. of the International Conference on the Science of Casting and Solidification, (2001), p. 336 [12] Morrogh and W.J.Williams: J.Iron Steel Inst., Vol. 155 (1947), p. 321 [13] Y.Tatsuzawa, S.Jung and H.Nakae: International Journal of Cast Metals Research, Vol. 21 (2008), p. 17 [14] Y.Tatsuzawa and H.Nakae: Journal of Japan Foundry Engineering Society, Vol. 82 (2010), p. 212-217 [15] N.Matsumoto, T.Misawa, S.Kubo and T.Ototani: The 1566th Report of the Research Institute for Iron, Steel and Other Metals, 1973, p. 87-96 [16] J.Park and S.Kim: Graphite Spherulites, Vol. 36 (1997), p. 1403
Online since: February 2016
Authors: Svetlana Kolupaeva, Aleksander Petelin, Yulia Petelina, Konstantin A. Polosukhin
Materials and methods
In [9], using the continuum theory of dislocations [10], a mathematical model of expansion of the closed dislocation loop and formation of the crystallographic shear zone was written.
Arakelyan, Analysis and mathematical simulation of motion of dislocations in aluminum single crystals, Journal of Contemporary Physics. 50 (2015) 95–100
Selivanikova, modeling of plastic deformation of crystalline materials on the basis of the concept of hardening and recovery, Russ.
Petelin, Software support for the mathematical modeling of plastic deformation in crystalline materials, Vestnik TSUAB (in Russian). 3 (2011) 159–163
Series: Materials Science and Engineering. 71 (2015) 012075
Arakelyan, Analysis and mathematical simulation of motion of dislocations in aluminum single crystals, Journal of Contemporary Physics. 50 (2015) 95–100
Selivanikova, modeling of plastic deformation of crystalline materials on the basis of the concept of hardening and recovery, Russ.
Petelin, Software support for the mathematical modeling of plastic deformation in crystalline materials, Vestnik TSUAB (in Russian). 3 (2011) 159–163
Series: Materials Science and Engineering. 71 (2015) 012075
Online since: October 2020
Authors: Hai Xu Liu, Xiao Feng Zhang, Yong Sheng Wang, Zhan Kui Wang, Jian Xiu Su
Stainless steel will become one of the main substrate materials for flexible large-scale displays.
Towards the optimization of materials and processes for flexible organic electronics devices [J].
The European Physical Journal Applied Physics, 2009,46(1) 12502(1-9)
Nature Materials, 2010, 9(11) 879-880
Journal of the Electrochemical Society of India. 1996, 45 (1) 50-52
Towards the optimization of materials and processes for flexible organic electronics devices [J].
The European Physical Journal Applied Physics, 2009,46(1) 12502(1-9)
Nature Materials, 2010, 9(11) 879-880
Journal of the Electrochemical Society of India. 1996, 45 (1) 50-52