Sort by:
Publication Type:
Open access:
Publication Date:
Periodicals:
Search results
Online since: November 2016
Authors: Fernanda A. Sampaio da Silva, Marcos Flavio de Campos, Edwin E.G. Rojas
The nanoparticle materials have been intensively studied in recent decades aiming mainly at the medical fields.
:Journal of Magnetism and Magnetic Materials Vol. 324 (2012), p. 4011
Araújo-Neto, et. al.: Journal of Magnetism and Magnetic Materials Vol. 364 (2014), p. 72
Wan: Journal of Colloid and Interface Science Vol. 305 (2007), p. 366
Schoen: Nanostructure Materials Vol. 5 (1995), p. 607.
:Journal of Magnetism and Magnetic Materials Vol. 324 (2012), p. 4011
Araújo-Neto, et. al.: Journal of Magnetism and Magnetic Materials Vol. 364 (2014), p. 72
Wan: Journal of Colloid and Interface Science Vol. 305 (2007), p. 366
Schoen: Nanostructure Materials Vol. 5 (1995), p. 607.
Online since: June 2012
Authors: Zheng Xin Tang, Xu Dong Zhou
McQueen, “New formula for calculating flow curves from high temperature constitutive data for 300 austenitic steels,” Journal of Materials Processing Technology Vol. 36(1), p. 31-42, 1992
Ruana, “Prediction of the flow stress of high-speed steel during hot deformation using a BP artificial neural network,” Journal of Materials Processing Technology Vol. 103 p. 200–205, 2000
Ruan, “Prediction of the flow stress of 0.4C–1.9Cr–1.5Mn–1.0Ni–0.2Mo steel during hot deformation,” Journal of Materials Processing Technology Vol. 116, p. 211-218, 2001
Lahiri, “Constitutive equation for elevated temperature flow behavior of plain carbon steels using dimensional analysis,” Journal of Materials Processing Technology Vol. 141, p. 219–227, 2003
Sun, “An ANFIS model for the prediction of flow stress of Ti600 alloy during hot deformation process,” Computational Materials Science Vol. 50, p. 2273–2279, 2011.
Ruana, “Prediction of the flow stress of high-speed steel during hot deformation using a BP artificial neural network,” Journal of Materials Processing Technology Vol. 103 p. 200–205, 2000
Ruan, “Prediction of the flow stress of 0.4C–1.9Cr–1.5Mn–1.0Ni–0.2Mo steel during hot deformation,” Journal of Materials Processing Technology Vol. 116, p. 211-218, 2001
Lahiri, “Constitutive equation for elevated temperature flow behavior of plain carbon steels using dimensional analysis,” Journal of Materials Processing Technology Vol. 141, p. 219–227, 2003
Sun, “An ANFIS model for the prediction of flow stress of Ti600 alloy during hot deformation process,” Computational Materials Science Vol. 50, p. 2273–2279, 2011.
Online since: March 2016
Authors: Guang Sheng Huang, Ding Kai Liu, Fu Sheng Pan, Ting Zhuang Han, Yan Chun Zhao
Effect of Na2SO4 on the Performance of Mg-air Battery
Yanchun Zhao1, 2, Guangsheng Huang1, 2, 3*, Dingkai Liu1, 2, Tingzhuang Han1, 2 and Fusheng Pan1, 2, 3
1State Key Laboratory of Mechanical Transmission, College of Materials Science and Engineering, Chongqing University, Chongqing 400044 China
2National Engineering Research Center for Magnesium Alloys, Chongqing University, Chongqing 400044 China
3Chongqing Research Center for Advanced Materials, Chongqing Academy of Science & Technology, Chongqing 401123 China
gshuang@cqu.edu.cn
Keywords: Na2SO4, Air cathode, Magnesium alloy, Mg-air battery, Electrochemical.
CDJZR14130009), Scientific and Technological Project of Chongqing Science and Technology Commission (No.
CSTC2012GGB50003) and Demonstrative Project of Chongqing Science and Technology Commission (No.
Ding, Flower-like CoS with nanostructures as a new cathode-active material for rechargeable magnesium batteries, Journal of Power Sources, 294 (2015) 643-649
Kuang, Carbon nanotubes as a secondary support of a catalyst layer in a gas diffusion electrode for metal air batteries, Journal of Colloid and Interface Science, 284 (2005) 593-599.
CDJZR14130009), Scientific and Technological Project of Chongqing Science and Technology Commission (No.
CSTC2012GGB50003) and Demonstrative Project of Chongqing Science and Technology Commission (No.
Ding, Flower-like CoS with nanostructures as a new cathode-active material for rechargeable magnesium batteries, Journal of Power Sources, 294 (2015) 643-649
Kuang, Carbon nanotubes as a secondary support of a catalyst layer in a gas diffusion electrode for metal air batteries, Journal of Colloid and Interface Science, 284 (2005) 593-599.
Online since: June 2015
Authors: Fernanda A. Sampaio da Silva, Marcos Flavio de Campos
Castro, M.F.de Campos: Journal of Magnetism and Magnetic Materials Vol. 328 (2013), p. 53
[14] M.F. de Campos: Materials Science Forum Vols. 660-661 (2010), p. 283
[19] M.F. de Campos, J.A. de Castro: Materials Science Forum Vols. 727-728 (2012), p. 140
[27] F.A.S. da Silva, M.F. de Campos: Materials Science Forum Vols. 727–728 (2012), p. 119
Altounian: Journal of Magnetism and Magnetic Materials Vol. 231 (2001), p. 219
[14] M.F. de Campos: Materials Science Forum Vols. 660-661 (2010), p. 283
[19] M.F. de Campos, J.A. de Castro: Materials Science Forum Vols. 727-728 (2012), p. 140
[27] F.A.S. da Silva, M.F. de Campos: Materials Science Forum Vols. 727–728 (2012), p. 119
Altounian: Journal of Magnetism and Magnetic Materials Vol. 231 (2001), p. 219
Online since: March 2008
Authors: Hui Ji Shi, Masataka Yatomi, Tao Yu
Then the model was used to study the creep damage development of a four-material notched
specimen of the welded joints which includes: base materials, coarse-grained HAZ, fine-grained
HAZ (type IV), and weld materials.
2.
Table1.Creep properties of materials at T=630 o C Table2.Creep damage properties of materials at T=630 o C 3.1 Uniaxial problem: The application of our creep damage constitutive model to a uniaxial stress situation is firstly discussed.
Andersson: Computational Materials Science, Vol. 25 (2002), p. 34-41 [5] A.C.F.
Ashby: Metal Science, August-September (1980), p. 395 [6] A.
Ashby: Progress in Materials Science, Vol. 27(1982), p.189-244 [7] Patrick Onck and Erik van der Giessen: Journal of the mechanics and physics of solids, Vol. 47(1999), p. 99-139 [8] Nonaka et. al.: JSMS, Vol.35 No. 390 (1986), p. 299-304 (in Japanese) [9] A.
Table1.Creep properties of materials at T=630 o C Table2.Creep damage properties of materials at T=630 o C 3.1 Uniaxial problem: The application of our creep damage constitutive model to a uniaxial stress situation is firstly discussed.
Andersson: Computational Materials Science, Vol. 25 (2002), p. 34-41 [5] A.C.F.
Ashby: Metal Science, August-September (1980), p. 395 [6] A.
Ashby: Progress in Materials Science, Vol. 27(1982), p.189-244 [7] Patrick Onck and Erik van der Giessen: Journal of the mechanics and physics of solids, Vol. 47(1999), p. 99-139 [8] Nonaka et. al.: JSMS, Vol.35 No. 390 (1986), p. 299-304 (in Japanese) [9] A.
Online since: March 2010
Authors: Zhi Chao Huang, Ze Jie Zhou, Wei Huang
The results show that SPR joining dissimilar materials of steel and aluminum alloy is feasible and
riveting joints take on high mechanical behavior.
Aluminum and steel are the most important construction materials for automotive structures.
The materials used for this test are 1.2mm 2A12 aluminum and 1.5mm DC01 cold-roll steel.
Acknowledgements The work reported herein was supported by National Natural Science Foundation of China (Grant No. 50665002), Natural Science Foundation of Jiangxi Province (Grant No. 2007GZC0869), Young Scientist Plan of Jiangxi Province, and Key Laboratory of Ministry of Education for Conveyance and Equipment (East China Jiaotong University).
References [1] X.Sun and M.A.Khaleel: International Journal of Impact Engineering Vol. 34(2007), p. 1668 [2] R.Porcaro, A.G.Hanssen, M.Langseth and A.Aalberg: Journal of Materials Processing Technology Vol.171 (2006), p 10 [3] R.J.Liu, S.W.Yu, C.J,Zhu and Y.C,Wang: Transaction of Beihua University Vol.8(2007),P. 369(In Chinese) [4] X.M.Chen, Z.C.Huang, S,W,Kang: S.W.Kang: Transaction of East-China Jiao-Tong University Vol. 25(2008), p. 106(In Chinese) [5] X.Sun, E.V.Stephens, and M.A.Khaleel: International Journal of Fatigue Vol. 29 (2007),P. 370
Aluminum and steel are the most important construction materials for automotive structures.
The materials used for this test are 1.2mm 2A12 aluminum and 1.5mm DC01 cold-roll steel.
Acknowledgements The work reported herein was supported by National Natural Science Foundation of China (Grant No. 50665002), Natural Science Foundation of Jiangxi Province (Grant No. 2007GZC0869), Young Scientist Plan of Jiangxi Province, and Key Laboratory of Ministry of Education for Conveyance and Equipment (East China Jiaotong University).
References [1] X.Sun and M.A.Khaleel: International Journal of Impact Engineering Vol. 34(2007), p. 1668 [2] R.Porcaro, A.G.Hanssen, M.Langseth and A.Aalberg: Journal of Materials Processing Technology Vol.171 (2006), p 10 [3] R.J.Liu, S.W.Yu, C.J,Zhu and Y.C,Wang: Transaction of Beihua University Vol.8(2007),P. 369(In Chinese) [4] X.M.Chen, Z.C.Huang, S,W,Kang: S.W.Kang: Transaction of East-China Jiao-Tong University Vol. 25(2008), p. 106(In Chinese) [5] X.Sun, E.V.Stephens, and M.A.Khaleel: International Journal of Fatigue Vol. 29 (2007),P. 370
Online since: July 2011
Authors: Zhi Fa Wang, Shu Bin Shen, Rui Sheng Wang, Li Xue Yu, Jing Long Bu, Rong Lin Wang
Experimental
Raw Materials.
Zhang: Aerospace Materials & Technology.
Zhou: Materials Science and Technology.
Dou: Rare Metal Materials and Engineering.
Huang: Journal of Inorganic Materials.
Zhang: Aerospace Materials & Technology.
Zhou: Materials Science and Technology.
Dou: Rare Metal Materials and Engineering.
Huang: Journal of Inorganic Materials.
Online since: April 2012
Authors: Hu Zhu, Wen Wen Lin, Jin Lan Bai
Filice et al: Journal of Materials Processing Technology Vol. 191(2007), p. 92-95
Szekeres et al: Journal of Materials Processing Technology Vol. 189(2007), p. 65-72
Giardini et al: Journal of Materials Processing Technology Vol. 197(2008), p. 59-67
Attanasio: Journal of Materials Processing Technology Vol. 152(2004), p. 176-84
Bay: Key Engineering Materials Vol. 344(2007), p. 583-590
Szekeres et al: Journal of Materials Processing Technology Vol. 189(2007), p. 65-72
Giardini et al: Journal of Materials Processing Technology Vol. 197(2008), p. 59-67
Attanasio: Journal of Materials Processing Technology Vol. 152(2004), p. 176-84
Bay: Key Engineering Materials Vol. 344(2007), p. 583-590
Online since: September 2016
Authors: Petr Kotlík, Adéla Peterová, Susana Garcia Mayo, Jakub Polonský, Vítězslav Knotek
The concept of the consolidation of materials is introduced to overcome this problem, or at least to reduce its severity.
Journal of Non-Crystalline Solids 311 (2002) 185–194
Chiantore, The protection of different italian marbles with two partially fluorinated acrylic copolymers, Applied Physics A Materials Science & Processing 79 (2004) 347–351
Journal of Cultural Heritage 10 (2009) 214–221
Esquivias, Stress During Drying of Two Stone Consolidants Applied in Monumental Conservation, Journal of Sol-Gel Science and Technology 26 (2003) 1227–1231
Journal of Non-Crystalline Solids 311 (2002) 185–194
Chiantore, The protection of different italian marbles with two partially fluorinated acrylic copolymers, Applied Physics A Materials Science & Processing 79 (2004) 347–351
Journal of Cultural Heritage 10 (2009) 214–221
Esquivias, Stress During Drying of Two Stone Consolidants Applied in Monumental Conservation, Journal of Sol-Gel Science and Technology 26 (2003) 1227–1231
Online since: March 2019
Authors: Arkady N. Soloviev, Le Van Duong, P.A. Oganesyan, E.V. Kirillova
Non-uniformly polarized piezoceramic materials can be used in effective energy harvesting devices.
Mathematical Model Let us examine a piezoelectric transducer Ω, presented by a set of areas Ωj = Ωpk; k = 1, 2,..., Np; j = k with the properties of piezoelectric materials, and a set of areas Ωj = Ωem; m = 1,2,...
,Ne; j = Np + m with the properties of elastic materials.
Comparison Between Applied Theory and Finite Element Method for Energy Harvesting Non-homogeneous Piezoelements Modeling. // Advanced Materials Techniques, Physics, Mechanics and Applications.
Journal of Applied Mechanics and Technical Physics, 42(1), 2001, 164-168
Mathematical Model Let us examine a piezoelectric transducer Ω, presented by a set of areas Ωj = Ωpk; k = 1, 2,..., Np; j = k with the properties of piezoelectric materials, and a set of areas Ωj = Ωem; m = 1,2,...
,Ne; j = Np + m with the properties of elastic materials.
Comparison Between Applied Theory and Finite Element Method for Energy Harvesting Non-homogeneous Piezoelements Modeling. // Advanced Materials Techniques, Physics, Mechanics and Applications.
Journal of Applied Mechanics and Technical Physics, 42(1), 2001, 164-168