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Online since: August 2012
Authors: Tao Yu, Si Li Chen, Jian Jun Shi, Kai He Dong, Jie Huang
,Journal of Basic Engng, p519~527(1963)
Journal of Shenyang Polytechnic University, p65-68 (1992)
[5] Jin Chen and Shushan Zhao: Fracture mechanics, edited by Science Press(2006)
Journal of Hydraulic Engineering ,p63~69 (1984)
Journal of Hydraulic Engineering, p27~37 (1982)
Journal of Shenyang Polytechnic University, p65-68 (1992)
[5] Jin Chen and Shushan Zhao: Fracture mechanics, edited by Science Press(2006)
Journal of Hydraulic Engineering ,p63~69 (1984)
Journal of Hydraulic Engineering, p27~37 (1982)
Online since: July 2014
Authors: Miao Ma, Jian Xiong Liu, Zheng Yu Wu, Xin Rui Zheng, Xiao Xiao Hu
Doped TiO2 nanotube for lithium ion battery
Xiaoxiao Hu1,a, Jianxiong Liu1,b*, Zhengyu Wu2,b, Xinrui Zheng1,c, Miao Ma1,d,
1Faculty of Materials Science and Engineering, 2Faculty of science
Kunming University of Science and Technology, Kunming 650093, China
ahbyshxx@163.com, bljx5192665@163.com, bWUZY501@163.com, czxr6684119@126.com, dmamiaokunming@163.com
Keywords: TiO2 nanotube, lithium ion battery, dope
Abstract.
Recently, studies exploring new electrode materials for LIBs have focused on reducing the size of materials to nanoscale.
However, TiO2 is a kind of semiconductor materials and it has a wide band gap (Anatase: 3.2eV, Rutile: 3.0eV), resulting in poor electrical conductivity.
However, the initial discharge capacity of all the coated materials suffered some loss in contrast to the uncoated TNTs.
Kim: Materials Chemistry and Physics 137 (2012) 169e176 [13] S.J.
Recently, studies exploring new electrode materials for LIBs have focused on reducing the size of materials to nanoscale.
However, TiO2 is a kind of semiconductor materials and it has a wide band gap (Anatase: 3.2eV, Rutile: 3.0eV), resulting in poor electrical conductivity.
However, the initial discharge capacity of all the coated materials suffered some loss in contrast to the uncoated TNTs.
Kim: Materials Chemistry and Physics 137 (2012) 169e176 [13] S.J.
Online since: March 2011
Authors: Yan He, Jun Ping Song, Lian Xiang Ma
Materials
The batch formula was normal.
Other materials were all purchased commercially.
Because of different raw material, processing and preparation method, different kinds of carbon black have different morphology and properties.
Acknowledgement The authors are grateful to National Natural Science Foundation of China (No. 50773034) and department of Science and Technology of Shandong province, P.R.China (No. 2008BS04028 and No.2009ZRB01071) for financial support of this project and are also grateful to Qingdao Municipal Science and Technology Commission for financial support in part of this project (No. 08-1-3-18-jch) References [1] G.T.Mohanraj, T.K.Chaki, and A.Chakraborty: Journal of Applied Polymer Science Vol.92(2004), p.2179 [2] A.R.Azura, Suriati Ghazali, and M.Mariatti: Journal of Applied Polymer Science Vol.110(2008), p.747 [3] Q.Q.Yang, J.Z.Liang: Applied Physics Letters Vol.93(2008) [4] Q.H.Zhang, D.J.Chen: Journal of Materials Science Vol.39(2004), p.1751 [5] L.Shen, Z.Y.Zhang, and J.J.Wang: Polymer Materials Science and Engineering Vol.22(2006), p.107 [6] Y.W.Wong, K.L.Lo, and F.G.Shin: Journal of Applied Polymer Science Vol.82(2001), p.1549 [7] G.M.Nasr, M.M.Badawy, and S.E.Gwaily
: Polymer Degradation and Stability Vol.48(1995),p.237 [8] A.Iqbal, L.Frormann, and A.Saleem: Polymer Composites (2007), p.186 [9] Y.He, H.T.Li, and L.X.Ma: Advanced Materials Research,Vol.87-88(2010), p.86 [10] Y.He,Z.Yin,L.X.Ma, and J.P.Song: Advanced Materials Research,Vol.87-88(2010), p.200 [11] J.P.Song, L.X.Ma: Advanced Materials Research,Vol.87-88(2010), p.536 [12] X.W.Zhang, R.Huang: China Plastic,8(1994), p.26
Other materials were all purchased commercially.
Because of different raw material, processing and preparation method, different kinds of carbon black have different morphology and properties.
Acknowledgement The authors are grateful to National Natural Science Foundation of China (No. 50773034) and department of Science and Technology of Shandong province, P.R.China (No. 2008BS04028 and No.2009ZRB01071) for financial support of this project and are also grateful to Qingdao Municipal Science and Technology Commission for financial support in part of this project (No. 08-1-3-18-jch) References [1] G.T.Mohanraj, T.K.Chaki, and A.Chakraborty: Journal of Applied Polymer Science Vol.92(2004), p.2179 [2] A.R.Azura, Suriati Ghazali, and M.Mariatti: Journal of Applied Polymer Science Vol.110(2008), p.747 [3] Q.Q.Yang, J.Z.Liang: Applied Physics Letters Vol.93(2008) [4] Q.H.Zhang, D.J.Chen: Journal of Materials Science Vol.39(2004), p.1751 [5] L.Shen, Z.Y.Zhang, and J.J.Wang: Polymer Materials Science and Engineering Vol.22(2006), p.107 [6] Y.W.Wong, K.L.Lo, and F.G.Shin: Journal of Applied Polymer Science Vol.82(2001), p.1549 [7] G.M.Nasr, M.M.Badawy, and S.E.Gwaily
: Polymer Degradation and Stability Vol.48(1995),p.237 [8] A.Iqbal, L.Frormann, and A.Saleem: Polymer Composites (2007), p.186 [9] Y.He, H.T.Li, and L.X.Ma: Advanced Materials Research,Vol.87-88(2010), p.86 [10] Y.He,Z.Yin,L.X.Ma, and J.P.Song: Advanced Materials Research,Vol.87-88(2010), p.200 [11] J.P.Song, L.X.Ma: Advanced Materials Research,Vol.87-88(2010), p.536 [12] X.W.Zhang, R.Huang: China Plastic,8(1994), p.26
Online since: October 2020
Authors: Yong Guo Wang, Y. Li, W. Yang, W.P. Dong, Wen Wang
Mechanical Engineering Materials [M].
Materials & design, 2007, 28(1): 101-111
Science and Technology,2015(13):82
Material constitutive equation and knife-chip friction characteristics for numerical simulation of metal cutting process[J].Journal of Sichuan University (Engineering Science Edition), 2012,44(06) ):181-18
Materials & Design, 2014,63:798-804 [16] Sun SY, Lv WJ (2016) Microstructure and Mechanical Properties of TC18 Titanium Alloy.
Materials & design, 2007, 28(1): 101-111
Science and Technology,2015(13):82
Material constitutive equation and knife-chip friction characteristics for numerical simulation of metal cutting process[J].Journal of Sichuan University (Engineering Science Edition), 2012,44(06) ):181-18
Materials & Design, 2014,63:798-804 [16] Sun SY, Lv WJ (2016) Microstructure and Mechanical Properties of TC18 Titanium Alloy.
Online since: June 2013
Authors: Philip Harrison, Farag Abdiwi, Woong Ryeol Yu
Effect of Tow Meander on the Shear Compliance of Woven Engineering Fabrics Measured using the Biaxial Bias Extension Test
Farag Abdiwi1, Philip Harrison1 and Woong-Ryeol Yu2
1 School of Engineering, James Watt Building (South)
University of Glasgow, Glasgow G12 8QQ, UK
2 Department of Materials Science and Engineering, 33 Dong 305 Ho, Seoul National University, 1 Gwanak-ro, Gwanak-gu, Seoul 151-742, South Korea
f.abdiwi.1@research.gla.ac.uk, Philip.Harrison@glasgow.ac.uk, woongryu@snu.ac.kr
Keywords: Biaxial bias extension test, woven engineering fabric, variability.
Composites Science and Technology, 72, (9), 1034–1041, 2012 [4] Prodromou, A. and Chen, J., On the Relationship between Shear Angle and Wrinkling of Textile Composites Preforms, Composites: Part A, (28): 491-503, 1997 [5] Wang, J., Predictive Modelling and Experimental Measurement of Composite Forming Behaviour, PhD Thesis, University of Nottingham, 2008 [6] Lussier, D., and Chen, J., Material Characterization of Woven Fabrics for Thermoforming of Composites, Journal of Thermoplastic Composite Materials, 15, 497-509, 2002 [7] Peng, X. and Cao, J., A Continuum Mechanics-Based Non-Orthogonal Constitutive Model for Woven Composite Fabrics, Composites: Part A, 36, 859–874, 2005 [8] Launay, L., Hivet, G., Duong, A. and Boisse, P., Experimental Analysis of the Influence of Tensions on in Plane Shear Behaviour of Woven Composite Reinforcements, Composites Science and Technology, 68, 2, 506–515, 2008 [9] Milani, A., Nemes, J., Lebrun, G., and Bureau, M., A Comparative Analysis of a Modified
Picture Frame Test for Characterization of Woven Fabrics, Polymer Composites, 31(4): 561-568, 2010 [10] Komeili, M. and Milani, A., Shear Response of Woven Fabric Composites under Meso-Level Uncertainties, Journal of Composite Materials, 1–11, 2012 [11] Hivet, G. and Duong, A., A Contribution to the Analysis of the Intrinsic Shear Behaviour of Fabrics, Journal of Composite Materials, 45(6), 695–716, 2010 [12] Harrison, P.
International Journal of Material Forming. 1:891-894, 2008 [14] Abdiwi, F., Harrison, P., Yu, W.R. and Guo, Z., Modelling the Shear-Tension Coupling of Engineering Fabrics.
Composites Part A: Applied Science and Manufacturing, 43 (9), 1546-1554, 2012
Composites Science and Technology, 72, (9), 1034–1041, 2012 [4] Prodromou, A. and Chen, J., On the Relationship between Shear Angle and Wrinkling of Textile Composites Preforms, Composites: Part A, (28): 491-503, 1997 [5] Wang, J., Predictive Modelling and Experimental Measurement of Composite Forming Behaviour, PhD Thesis, University of Nottingham, 2008 [6] Lussier, D., and Chen, J., Material Characterization of Woven Fabrics for Thermoforming of Composites, Journal of Thermoplastic Composite Materials, 15, 497-509, 2002 [7] Peng, X. and Cao, J., A Continuum Mechanics-Based Non-Orthogonal Constitutive Model for Woven Composite Fabrics, Composites: Part A, 36, 859–874, 2005 [8] Launay, L., Hivet, G., Duong, A. and Boisse, P., Experimental Analysis of the Influence of Tensions on in Plane Shear Behaviour of Woven Composite Reinforcements, Composites Science and Technology, 68, 2, 506–515, 2008 [9] Milani, A., Nemes, J., Lebrun, G., and Bureau, M., A Comparative Analysis of a Modified
Picture Frame Test for Characterization of Woven Fabrics, Polymer Composites, 31(4): 561-568, 2010 [10] Komeili, M. and Milani, A., Shear Response of Woven Fabric Composites under Meso-Level Uncertainties, Journal of Composite Materials, 1–11, 2012 [11] Hivet, G. and Duong, A., A Contribution to the Analysis of the Intrinsic Shear Behaviour of Fabrics, Journal of Composite Materials, 45(6), 695–716, 2010 [12] Harrison, P.
International Journal of Material Forming. 1:891-894, 2008 [14] Abdiwi, F., Harrison, P., Yu, W.R. and Guo, Z., Modelling the Shear-Tension Coupling of Engineering Fabrics.
Composites Part A: Applied Science and Manufacturing, 43 (9), 1546-1554, 2012
Online since: June 2015
Authors: S. Prakash, M. Sangeetha
Figure.2 shows the elongation values for different combination of materials.
combination of Materials Fig.3, Vickers Hardness Value for different combination of Materials 4.
Journal of Minerals & Materials Characterization & Engineering, Vol. 8, 2009, pp 455-467
Rashad.R.M , Awadallah.O.M and Wifi.A.S “Effect of MWCNTs content on the Characteristics of A356 nano composite, “, Journal of achievements in Material And Manufacturing engineering, vo l- 58, june 2013, issue 2
S.Charles and V.P.Arunachalam, “Property Analysis and Mathematical Modelling of mechanical Properties of Aluminium alloy and hybrid composites produced by liquid metallurgy and powder metallurgy techniques”, “Indian Journal of Engineering and Material Science”, Vol-11, 2004, pp-473-480.
combination of Materials Fig.3, Vickers Hardness Value for different combination of Materials 4.
Journal of Minerals & Materials Characterization & Engineering, Vol. 8, 2009, pp 455-467
Rashad.R.M , Awadallah.O.M and Wifi.A.S “Effect of MWCNTs content on the Characteristics of A356 nano composite, “, Journal of achievements in Material And Manufacturing engineering, vo l- 58, june 2013, issue 2
S.Charles and V.P.Arunachalam, “Property Analysis and Mathematical Modelling of mechanical Properties of Aluminium alloy and hybrid composites produced by liquid metallurgy and powder metallurgy techniques”, “Indian Journal of Engineering and Material Science”, Vol-11, 2004, pp-473-480.
Online since: July 2016
Authors: Chun Lei Wan, Kaleem Ahmad, Hany S. Abdo, Mohammad A. Al-Eshaikh, Ahmed N. Kadachi, Rawaiz Khan
Abdoe
a*Sustainable energy technologies center, College of Engineering, King Saud University
bStateKey Laboratory of New Ceramics and Fine Processing, School of Materials Science and Engineering, Tsinghua University, Beijing 100084, China
cResearch Center, College of Engineering, King Saud University, PO Box 800, Riyadh 11421, Saudi Arabia
eCenter of Excellence for Research in Engineering Materials (CEREM), Advanced Manufacturing Institute, King Saud University, P.O.
There are continued efforts to developemerging functional and structural materials to improve safety of nuclear power reactors.
Qin, et al., "Enhanced thermoelectric figure of merit in p-type Bi0.48Sb1.52Te3 alloy with WSe2 addition," Journal of Materials Chemistry A, vol. 2, pp. 8512-8516, 2014
Khaliq, et al., "Large ZT enhancement in hot forged nanostructured p-type Bi0.5Sb1.5Te3 bulk alloys," Journal of Materials Chemistry A, vol. 2, pp. 5785-5790, 2014
Ioannou, et al., "Seebeck and thermal conductivity analysis in amorphous/crystalline β-K2Bi8Se13 nanocomposite materials," J.
There are continued efforts to developemerging functional and structural materials to improve safety of nuclear power reactors.
Qin, et al., "Enhanced thermoelectric figure of merit in p-type Bi0.48Sb1.52Te3 alloy with WSe2 addition," Journal of Materials Chemistry A, vol. 2, pp. 8512-8516, 2014
Khaliq, et al., "Large ZT enhancement in hot forged nanostructured p-type Bi0.5Sb1.5Te3 bulk alloys," Journal of Materials Chemistry A, vol. 2, pp. 5785-5790, 2014
Ioannou, et al., "Seebeck and thermal conductivity analysis in amorphous/crystalline β-K2Bi8Se13 nanocomposite materials," J.
Online since: June 2014
Authors: Wu Di Zhang, Li Juan Zhang, Fang Yin, Xing Ling Zhao, Jing Liu, Shi Qing Liu, Yu Bao Chen, Hong Yang
Materials and Methods
Materials.
Journal of Anhui Agricultural Science.
Northwest Pharmaceutical Journal.
Journal of Farm Machinery Research.
Journal of Anhui Agricultural Science.
Journal of Anhui Agricultural Science.
Northwest Pharmaceutical Journal.
Journal of Farm Machinery Research.
Journal of Anhui Agricultural Science.
Online since: July 2013
Authors: Lian Xiang Ma, Gang Yang, Yuan Zheng Tang, Yan He
The EMD method is based on the linear response theory, using the Einstein or Green-Kubo (GK) formula to calculate thermal conductivity of bulk materials.
The molecular structure of EPDM is built by Materials Studio® software [12].
The EMD method is based on the linear response theory, using the Einstein or GK formula to calculate thermal conductivity of bulk materials.
Lee: Journal of Applied Polymer Science, Vol.16(1972), p.3159 [2] C.
Bollampally: Journal of Polymer Science, Vol.74(1999), p.3396 [3] V.
The molecular structure of EPDM is built by Materials Studio® software [12].
The EMD method is based on the linear response theory, using the Einstein or GK formula to calculate thermal conductivity of bulk materials.
Lee: Journal of Applied Polymer Science, Vol.16(1972), p.3159 [2] C.
Bollampally: Journal of Polymer Science, Vol.74(1999), p.3396 [3] V.
Online since: June 2014
Authors: Samuel Marcio Toffoli, Ticiane Sanches Valera, Douglas Morais, Natalia Massaro
Experimental
Materials.
Xu: Journal of Hazardous Materials Vol. 243 (2012), p. 311
Lin: Journal of Hazardous Materials Vol. 148 (2007), p. 91
Rybnikár: Journal of Applied Polymer Science Vol. 42 (1991), p. 2727
Matsuda: Journal of Applied Polymer Science Vol. 79 (2001), p. 1693.
Xu: Journal of Hazardous Materials Vol. 243 (2012), p. 311
Lin: Journal of Hazardous Materials Vol. 148 (2007), p. 91
Rybnikár: Journal of Applied Polymer Science Vol. 42 (1991), p. 2727
Matsuda: Journal of Applied Polymer Science Vol. 79 (2001), p. 1693.