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Online since: September 2011
Authors: Wen Zhong Qu, Li Xiao, Yan Guo Zhou
To MR as a typical, the dynamic model for hysteresis behavior of materials is an important topic in its application in practical engineering.
Journal of Vibration Engineering(In Chinese), Vol. 14(2001),p. 334
Journal of Dynamics and Control(In Chinese), Vol. 4 (2006), p. 8
Chinese Journal of Materials Research, Vol.17(2003), p.499
Hysteresis Vibration System and Engineering Application, Beijing,Science Press,2002.
Journal of Vibration Engineering(In Chinese), Vol. 14(2001),p. 334
Journal of Dynamics and Control(In Chinese), Vol. 4 (2006), p. 8
Chinese Journal of Materials Research, Vol.17(2003), p.499
Hysteresis Vibration System and Engineering Application, Beijing,Science Press,2002.
Online since: February 2013
Authors: Qing Cao, Xu Jiang, Zhao Yu, Hong Hui Zhang
Intelligent Material Systems and Structures, 2002, 13(7/8):443-451
Journal of Function Materials, 2006, 5(37):736-738.
Chinese Journal of Scientific Instrument, 2006, 27(8):928-931.
Chinese Journal of Automotive Engineering, 2011, 1(4):336-341
Journal of Function Materials, 2006, 5 (37): 745 -747.
Journal of Function Materials, 2006, 5(37):736-738.
Chinese Journal of Scientific Instrument, 2006, 27(8):928-931.
Chinese Journal of Automotive Engineering, 2011, 1(4):336-341
Journal of Function Materials, 2006, 5 (37): 745 -747.
Online since: September 2025
Authors: Masashi Kato, Tong Li, Michael Rueb, Hitesh Jayaprakash, Constantin Csato, Florian Krippendorf
In:
Materials Science Forum 1062 (2022), pp. 125-130
In: Materials Science Forum 353-356 (2001), pp. 299-302
Materials Science Forum.
In: Materials Science in Semiconductor Processing 153 (2023), p. 107126
In: Materials Science Forum 1062 (2022), pp. 273-277.[20] Kazumi Takano et al.
In: Materials Science Forum 353-356 (2001), pp. 299-302
Materials Science Forum.
In: Materials Science in Semiconductor Processing 153 (2023), p. 107126
In: Materials Science Forum 1062 (2022), pp. 273-277.[20] Kazumi Takano et al.
Online since: July 2020
Authors: Xiu Liu, Xiao Mei Yu, Chuang Xu, Jiang Wei Chu
Construction and Building Materials, 2019, 195: 450-458
Construction and Building Materials, 2019, 202: 58-72
Journal of Building Materials, 2008, 11 (5) : 612-615
Journal of Materials Science, 2005, 40 (1) : 87-95
Journal of Xi'an University of Architecture and Technology: Natural Science Edition, 2005, 37 (1) : 104-107
Construction and Building Materials, 2019, 202: 58-72
Journal of Building Materials, 2008, 11 (5) : 612-615
Journal of Materials Science, 2005, 40 (1) : 87-95
Journal of Xi'an University of Architecture and Technology: Natural Science Edition, 2005, 37 (1) : 104-107
Online since: December 2011
Authors: Yuan Lin Zhou, Ying Jun Li, Shi Kai Luo, Li Li, Shao Tao Zheng
Study on the Preparation and Properties of Low Permeability Coating
Yingjun Li1, a, Yuanlin Zhou2,b, Shikai Luo3,c, Li Li4,d, Shaotao Zheng5,f
1,2State Key Laboratory Cultivation Base for Nonmetal Composite and Functional Materials, Southwest University of Science and Technology, Mianyang, Sichuan, China
3,4,5Institute of Materials, China Academy of Engineering Physics, Mianyang, Sichuan, China
aLiyingjun198@163.com, bzyl603@163.com
Keywords: coating; solubility parameter; F2314 resin; FEVE resin; permeability
Abstract.
Therefore, it is widely used in biological and medical treatment [2], cultural relic protection [3], magnetic materials [4] and other many fields in United States and other countries.
Wang, Journal of Tongji University(Natural Science Edition), vol. 10 (2005), p. 13371
Yan, Magnetic Materials and Devices, vol. 8 (2000), p. 81
Xu, Beijing Science and Technology (1981).
Therefore, it is widely used in biological and medical treatment [2], cultural relic protection [3], magnetic materials [4] and other many fields in United States and other countries.
Wang, Journal of Tongji University(Natural Science Edition), vol. 10 (2005), p. 13371
Yan, Magnetic Materials and Devices, vol. 8 (2000), p. 81
Xu, Beijing Science and Technology (1981).
Online since: November 2011
Authors: Guo Qing Zhang, Zhou Li, Wen Yong Xu
Low cycle fatigue behavior of spray formed superalloy rings
Wenyong Xua, Guoqing Zhangb and Zhou Lic
Science and Technology on Advanced High Temperature Structural Materials Laboratory, Beijing Institute of Aeronautical Materials (BIAM), Beijing 100095, China
axwybiam@126.com, bg.zhang@126.com, clibiam@126.com
Keywords: sprayforming; superalloy; GH738; low cycle fatigue
Abstract.
Experiment The materials studied in the present investigation are the nickel-base superalloy GH738, whose nominal composition is (in wt%):Cr 19.6, Mo 4.3, Co 13.5, Ti 3.1, Al 1.5, B 0.008, and bal.
References [1] D.S.Wei, X.G.Yang: International Journal of Pressure Vessels and Piping Vol.86 (2009), p.616
[2] N.Muhammad: Journal of Engineering for Gas Turbines and Power Vol.131 (2009), p525 [3] K.Gopinath, A.K.
Gogia, S.V.Kamat: Acta Materialia Vol.57 (2009), 34 [4] Keh-Minn Chang, Liu X B: Materials Science and Engineer A Vol.308 (2001), p1 [5] A.Abdul, V.Ferney, K.Saanouni: Transactions of the ASME Vol.121 (1999), p278 [6] J.T.Yeom, S.J.Williams, N.K.Park: Material at High temperatures Vol.19 (2002), p153 [7] D.L.Davidson, R.G.Tryon, M.Oja: Metallurgical and Materials Transactions A Vol.38A(2007), p2214 [8] P.J.Phillips, R.R.Unocic, L.Kovarik: Scripta materialia Vol.62(2010), p790 [9] K.Obrtlik, A.Chlupova, M.Petrenec: Key Engineering Materials Vol.385-387(2008), p581 [10] J.J.Yu, X.F.Sun, T.Jin: Materials Science and Engineering A Vol.527(2010), p2379 [11] M.Marchionni,G.A.Osinkolu,G.Onofrio: International Journal of Fatigue Vol.24 (2002), p1261
Experiment The materials studied in the present investigation are the nickel-base superalloy GH738, whose nominal composition is (in wt%):Cr 19.6, Mo 4.3, Co 13.5, Ti 3.1, Al 1.5, B 0.008, and bal.
References [1] D.S.Wei, X.G.Yang: International Journal of Pressure Vessels and Piping Vol.86 (2009), p.616
[2] N.Muhammad: Journal of Engineering for Gas Turbines and Power Vol.131 (2009), p525 [3] K.Gopinath, A.K.
Gogia, S.V.Kamat: Acta Materialia Vol.57 (2009), 34 [4] Keh-Minn Chang, Liu X B: Materials Science and Engineer A Vol.308 (2001), p1 [5] A.Abdul, V.Ferney, K.Saanouni: Transactions of the ASME Vol.121 (1999), p278 [6] J.T.Yeom, S.J.Williams, N.K.Park: Material at High temperatures Vol.19 (2002), p153 [7] D.L.Davidson, R.G.Tryon, M.Oja: Metallurgical and Materials Transactions A Vol.38A(2007), p2214 [8] P.J.Phillips, R.R.Unocic, L.Kovarik: Scripta materialia Vol.62(2010), p790 [9] K.Obrtlik, A.Chlupova, M.Petrenec: Key Engineering Materials Vol.385-387(2008), p581 [10] J.J.Yu, X.F.Sun, T.Jin: Materials Science and Engineering A Vol.527(2010), p2379 [11] M.Marchionni,G.A.Osinkolu,G.Onofrio: International Journal of Fatigue Vol.24 (2002), p1261
Online since: May 2022
Authors: Victor Tochukwu Ibeabuchi, Clifford Ugochukwu Nwoji, Chizoo Esonye
Hence, from Table 1, CES material meets the requirement as pozzolanic materials.
Materials Today: Proceedings, 45(2021) 884-890 [2] K.
Journal, 95(2018)66–76
Construction and Building Materials, 215(2019) 233–243
Construction and Building Materials, 41 (2013) 21–25.
Materials Today: Proceedings, 45(2021) 884-890 [2] K.
Journal, 95(2018)66–76
Construction and Building Materials, 215(2019) 233–243
Construction and Building Materials, 41 (2013) 21–25.
Online since: October 2010
Authors: Aliye Arabaci, Nuri Solak
However, such a high operating temperature may cause a great challenge to the materials used in the fuel cell such as thermal mismatch among these materials.
Cerium and gadolinium acetate hydrate (99.99 % Aldrich) were used as starting materials.
Wenhui: Journol of Memrane Science, Vol. 286 (2006), p.255 [2] R.O.
Meng: Materials Chemistry and Physics , Vol. 78 (2003), p. 791 [4] Z.C.
Muccillo: Materials Research Bulletin, Vol.38 (2003), p.1979
Cerium and gadolinium acetate hydrate (99.99 % Aldrich) were used as starting materials.
Wenhui: Journol of Memrane Science, Vol. 286 (2006), p.255 [2] R.O.
Meng: Materials Chemistry and Physics , Vol. 78 (2003), p. 791 [4] Z.C.
Muccillo: Materials Research Bulletin, Vol.38 (2003), p.1979
Online since: August 2019
Authors: Rahul Singh, Kannan Sekar
In this paper, the hybrid composites of A7050/Al2O3/ZrO2 with different wt. % of reinforcement materials (0.5, 1, 1.5wt. % ZrO2, and 1wt. % Al2O3 constant for all composites) were fabricated by stir casting method.
Brechet, “On the relationship between microstructure, strength and toughness in AA7050 aluminum alloy”, Materials Science and Engineering A356 (2003) 326-336
Mohan, “Influence of stirring speed and stirring time on distribution of particles in cast metal matrix composite”, Journal of Materials Processing Technology 171 (2006) 268–273
Baghchesara, “Investigation into the mechanical properties and fracture behavior of A356 aluminum alloy-based zro2-particle-reinforced metal-Matrix composites”, Mechanics of Composite Materials, 49 (2013) 849-858
[10] ErvinaEfzanM.N ,SitiSyazwani N , and Mohd Mustafa Al Bakri Abdullah “Fabrication Method of Aluminum Matrix Composite (Amcs): A Review”, Key Engineering Materials, 700 (2016) 102-110.
Brechet, “On the relationship between microstructure, strength and toughness in AA7050 aluminum alloy”, Materials Science and Engineering A356 (2003) 326-336
Mohan, “Influence of stirring speed and stirring time on distribution of particles in cast metal matrix composite”, Journal of Materials Processing Technology 171 (2006) 268–273
Baghchesara, “Investigation into the mechanical properties and fracture behavior of A356 aluminum alloy-based zro2-particle-reinforced metal-Matrix composites”, Mechanics of Composite Materials, 49 (2013) 849-858
[10] ErvinaEfzanM.N ,SitiSyazwani N , and Mohd Mustafa Al Bakri Abdullah “Fabrication Method of Aluminum Matrix Composite (Amcs): A Review”, Key Engineering Materials, 700 (2016) 102-110.
Online since: July 2011
Authors: Jun Hong Qiu, Jiang Nan Shen, Yun Fei Ye, Gan Ning Zeng
Preparation and characterization of PMMA-b-PDMAEMA/polysulfone composite membranes by RAFT polymerization and their permeation performance of carbon dioxide
Jiang-nan Shen1,a, Yun-fei Ye1, Gan-ning Zeng1, Jun-hong Qiu1
1 College of Chemical Engineering and Materials Science, Zhejiang University of Technology, Hangzhou 310014, China
ashenjn@zjut.edu.cn
Keywords: PMMA-b-PDMAEMA, RAFT polymerization, membrane permeation, Carbon dioxide
Abstract: PMMA-b-PDMAEMA/polysulfone composite membranes for CO2 separation was prepared by reversible addition-fragmentation chain transfer (RAFT) polymerization techniques.
Experimental Materials MMA and DMAEMA were purified by vacuum distillation, 2,2´-azo-bis(isobutyronitrile (AIBN), were used as received, The chain transfer agent (CTA): monocarboxyl-terminated trithiocarbonate derivative (MTTCD) was prepared according to the published document[19].
Australian Journal of Chemistry, 2005,58(6):379-410
[14]K.Xu, W.D.Zhang, Y.M.Yue, P.X.Wang, Journal of Applied Polymer Science, 2005, 98(3):1050-1054
[16] N.Gaillard, A.Guyot, J.Claverie, Journal of Polymer Polymer Science A-Polymer Chemistry, 2003, 41(5):684-698
Experimental Materials MMA and DMAEMA were purified by vacuum distillation, 2,2´-azo-bis(isobutyronitrile (AIBN), were used as received, The chain transfer agent (CTA): monocarboxyl-terminated trithiocarbonate derivative (MTTCD) was prepared according to the published document[19].
Australian Journal of Chemistry, 2005,58(6):379-410
[14]K.Xu, W.D.Zhang, Y.M.Yue, P.X.Wang, Journal of Applied Polymer Science, 2005, 98(3):1050-1054
[16] N.Gaillard, A.Guyot, J.Claverie, Journal of Polymer Polymer Science A-Polymer Chemistry, 2003, 41(5):684-698