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Online since: June 2019
Authors: Zhen Fa Liu, Ai Jia Wei, Wen Li, Li Hui Zhang
Spine LiNi0.5Mn1.5O4 (LNMO) is considered as one of the most attractive cathode materials due to its high operating voltage (at about 4.7V vs Li+) and high specific energy of 658 Wh kg-1, which is much higher than commercial cathode materials such as LiCoO2 (518 Wh kg-1), LiMn2O4 (400 Wh kg-1), LiFePO4 (495 Wh kg-1), and LiCo1/3Ni1/3Mn1/3O2 (576 Wh kg-1).
The structural properties and electrochemical performances of the as-obtained materials are investigated and reported below . 2 Material and Methods 2.1 Synthesis and characterization Li2CO3 (99%, Aladdin), MnO2 (90%, Aladdin), NiO (99.9%, Aladdin), and Nd2O3 (99.9%, Aladdin) were used as raw materials.
Chiang, Science, 330, 1485 (2010) [2] J.M.
Tong, Materials Chemistry and Physics, 2013, 138: 716–723
Nan, Chemistry of Materials. 2015, 27: 7734−7742 [23] Y.
The structural properties and electrochemical performances of the as-obtained materials are investigated and reported below . 2 Material and Methods 2.1 Synthesis and characterization Li2CO3 (99%, Aladdin), MnO2 (90%, Aladdin), NiO (99.9%, Aladdin), and Nd2O3 (99.9%, Aladdin) were used as raw materials.
Chiang, Science, 330, 1485 (2010) [2] J.M.
Tong, Materials Chemistry and Physics, 2013, 138: 716–723
Nan, Chemistry of Materials. 2015, 27: 7734−7742 [23] Y.
Online since: July 2015
Authors: Xin Liu, Gang Meng, Run Hui Wu, Jia Qi Liu, Ai Min Ren, Sheng Jun Zhang
Journal of Functional Materials, 15,Vol(44) , 2013:p2170-2174
Radiation Effect of Porous Materials with Cylindrical Cavities.
Science & Technology Review, 30,Vol(32),2012: p67-70
Journal of Zhengzhou University(Engineering Science, 3,Vol(33),2012: p87-90
Journal of Sichuan University(Engineering Science Edition, 3,Vol(30),2013: p381-385
Radiation Effect of Porous Materials with Cylindrical Cavities.
Science & Technology Review, 30,Vol(32),2012: p67-70
Journal of Zhengzhou University(Engineering Science, 3,Vol(33),2012: p87-90
Journal of Sichuan University(Engineering Science Edition, 3,Vol(30),2013: p381-385
Online since: July 2013
Authors: Xiao Hui Zeng, Wen Lang Luo, Deng Li Bo, Jing Zhong Li, Chen Zhang
Introduction
In the field of nano-materials research, researchers often use the parallel computer system for design and simulation to save research time and funding [1, 2, 3, 4, 5, 6], which can quickly obtain materials structure, properties and intrinsic mechanisms.
Multimillion atom simulation of materials on parallel computers-nanopixel, interracial fracture, nanoindentation, and oxidation [J].
Chinese Journal of Computers, 2006, 29(7): 1217-1224 [11] WANG Wei, ZENG Guo-Sun.
Science in China(Series E:Information Sciences), 2007, 37(2): 285-296 [12] William Gropp, Ewing Lusk.
The International Journal of High Performance Computing Applications, Volume 18, No. 3, Fall 2004
Multimillion atom simulation of materials on parallel computers-nanopixel, interracial fracture, nanoindentation, and oxidation [J].
Chinese Journal of Computers, 2006, 29(7): 1217-1224 [11] WANG Wei, ZENG Guo-Sun.
Science in China(Series E:Information Sciences), 2007, 37(2): 285-296 [12] William Gropp, Ewing Lusk.
The International Journal of High Performance Computing Applications, Volume 18, No. 3, Fall 2004
Online since: October 2011
Authors: Yang Wang, Xue Feng Wu, Xiang Wei Wang, Hong Zhi Zhang, Li Jun Yan
Laser assisted milling (LAML) is a potential method for machining difficult-to-machine materials such as superalloys and ceramics, which uses a high power laser to focally heat a workpiece prior to material removal with a traditional cutting tool.
LAML is also a potential machining method with the ability of machining planes and grooves of difficult-to-machine materials.
Melkote [12] developed a novel laser assisted micro-milling mach-ine to enable the creation of freeform three-dimensional micro-scale features in hard materials.
The main cutting force is greater than axial force and it is the common characteristics of cutting plastic materials.
References [1] Rozzi JC, Pfefferkorn FE, Shin YC: Journal of Manufacturing Science and Engineering Vol.122(4) (2000), p. 666-670 [2] Rebro PA, Shin YC, Incropera FP: Journal of Manufacturing Science and Engineering Vol.124(4) (2002), p. 875-885 [3] Pfefferkorn FE, Shin YC, Tian Y: Journal of Manufacturing Science and Engineering Vol.126(1) (2004), p.42-51 [4] Anderson M, Patwa R, Shin YC: International Journal of Machine Tools and Manufacture Vol.46(14) (2006), p.1879-1891 [5] Skvarenina S, Shin YC: International Journal of Machine Tools and Manufacture Vol.46(1) (2006),p.7-17 [6] Anderson MC, Shin YC: Proceedings of the Institution of Mechanical Engineers, Part B: Journal of Engineering Manufacture Vol.220(12) (2006), p.2055-2067 [7] Konig W, Zaboklicki A K: NIST Special Publication, Gaithersburg, MD Vol. 847 (1993), p.455–463 [8] Shen, X. and S.
LAML is also a potential machining method with the ability of machining planes and grooves of difficult-to-machine materials.
Melkote [12] developed a novel laser assisted micro-milling mach-ine to enable the creation of freeform three-dimensional micro-scale features in hard materials.
The main cutting force is greater than axial force and it is the common characteristics of cutting plastic materials.
References [1] Rozzi JC, Pfefferkorn FE, Shin YC: Journal of Manufacturing Science and Engineering Vol.122(4) (2000), p. 666-670 [2] Rebro PA, Shin YC, Incropera FP: Journal of Manufacturing Science and Engineering Vol.124(4) (2002), p. 875-885 [3] Pfefferkorn FE, Shin YC, Tian Y: Journal of Manufacturing Science and Engineering Vol.126(1) (2004), p.42-51 [4] Anderson M, Patwa R, Shin YC: International Journal of Machine Tools and Manufacture Vol.46(14) (2006), p.1879-1891 [5] Skvarenina S, Shin YC: International Journal of Machine Tools and Manufacture Vol.46(1) (2006),p.7-17 [6] Anderson MC, Shin YC: Proceedings of the Institution of Mechanical Engineers, Part B: Journal of Engineering Manufacture Vol.220(12) (2006), p.2055-2067 [7] Konig W, Zaboklicki A K: NIST Special Publication, Gaithersburg, MD Vol. 847 (1993), p.455–463 [8] Shen, X. and S.
Online since: October 2011
Authors: You Xi Lin, Cheng Hui Gao, Zhi Hua Chen
Friction materials used in the automobile brakes can be classified into non-asbestos organic (NAO),semi-metallic and ceramic types.
The main problem in the development of brake material is what the materials are and how much they are mixed.
With the development of computer science especially artificial intelligent technologies some progress have been made in the fields of material processing and design.
Qi and H.M.Han:Journal of Materials Processing Technology,Vol.151(2004),p.126
[7] J.R.Cho and S.W.Shin:Composites Part A: Applied Science and Manufacturing, Vol.35(2004),p.585
The main problem in the development of brake material is what the materials are and how much they are mixed.
With the development of computer science especially artificial intelligent technologies some progress have been made in the fields of material processing and design.
Qi and H.M.Han:Journal of Materials Processing Technology,Vol.151(2004),p.126
[7] J.R.Cho and S.W.Shin:Composites Part A: Applied Science and Manufacturing, Vol.35(2004),p.585
Online since: December 2013
Authors: Aklilu Tesfamichael Baheta, Hussain Hamoud Al-Kayiem, Saw Chun Lin, Lukmon Owolabi Afolabi
Phase change materials (PCM) are widely used as heat transfer medium in TES, this materials offer a challenging options to be employed as an effective energy storage and retrieval mechanics [2].
Materials and methods.
Kenisarina, "Form-stable phase change materials for thermal energy storage," Renewable and Sustainable Energy Reviews, vol. 16, pp. 1999-2040, 2012
Septiadi, "Experimental investigation of thermal conductivity and heat pipe thermal performance of ZnOnanofluids," International Journal of Thermal Sciences, 2012
Wang, "Enhanced Thermal Conductivity of Liquid Paraffin Based Nanofluids Containing Copper Nanoparticles," Journal of Dispersion Science and Technology, vol. 32, pp. 948-951, 2011
Materials and methods.
Kenisarina, "Form-stable phase change materials for thermal energy storage," Renewable and Sustainable Energy Reviews, vol. 16, pp. 1999-2040, 2012
Septiadi, "Experimental investigation of thermal conductivity and heat pipe thermal performance of ZnOnanofluids," International Journal of Thermal Sciences, 2012
Wang, "Enhanced Thermal Conductivity of Liquid Paraffin Based Nanofluids Containing Copper Nanoparticles," Journal of Dispersion Science and Technology, vol. 32, pp. 948-951, 2011
Online since: January 2011
Authors: Kikuo Kishimoto, Yi Ze Wang, Feng Ming Li
Box 137, School of Astronautics, Harbin Institute of Technology, Harbin 150001, P R China
2Department of Mechanical Sciences and Engineering, Tokyo Institute of Technology, 2-12-1, O-okayama, Meguro-ku, Tokyo 152-8552, Japan
awangyize@gmail.com, bfmli@hit.edu.cn, ckkishimo@mep.titech.ac.jp
Keywords: Flexural wave, Localization, Band gap materials, Random disorder, Axial load
Abstract.
Introduction In recent years, there is a lot of attention on the study of wave propagation in periodic composite materials which are also called the band gap materials [1,2].
With this characteristic, the band gap materials have many potential applications such as the acoustic transducers and filters and the vibration isolation technology.
As a result, there is a growing interest on the band gap materials with both theoretical and experimental investigations [3–6].
It should be noted that in the practical applications, due to the error in the manufacture, the random disorders cannot be avoided and the band gap materials become the randomly disordered system.
Introduction In recent years, there is a lot of attention on the study of wave propagation in periodic composite materials which are also called the band gap materials [1,2].
With this characteristic, the band gap materials have many potential applications such as the acoustic transducers and filters and the vibration isolation technology.
As a result, there is a growing interest on the band gap materials with both theoretical and experimental investigations [3–6].
It should be noted that in the practical applications, due to the error in the manufacture, the random disorders cannot be avoided and the band gap materials become the randomly disordered system.
Online since: December 2023
Authors: Saffa Nader Jihad, Khitam Abdulhussein Saeed
Materials and Methods
Materials
Silty Clay Soil
One type of soil was selected in this study.
This test was an indication of the formation of cementitious materials.
Role of organic amendments on enhanced bioremediation of heavy metal (loid) contaminated soils, Journal of hazardous materials, 185(2–3) (2011) 549–574
ARPN Journal of Engineeringand Applied Sciences, 11(8) 2016 5365-5371
Saeed et al., Comparison of Compressibility Behaviour of Lime-Cement Stabilized Lateritic Clay Soil Contaminated by Heavy Metals, in IOP Conference Series: Materials Science and Engineering.
This test was an indication of the formation of cementitious materials.
Role of organic amendments on enhanced bioremediation of heavy metal (loid) contaminated soils, Journal of hazardous materials, 185(2–3) (2011) 549–574
ARPN Journal of Engineeringand Applied Sciences, 11(8) 2016 5365-5371
Saeed et al., Comparison of Compressibility Behaviour of Lime-Cement Stabilized Lateritic Clay Soil Contaminated by Heavy Metals, in IOP Conference Series: Materials Science and Engineering.
Online since: December 2010
Authors: Ya Xiong Liang, Yu Wen Li, Yan Peng Zhu, Ya Ling Chou
Cold Regions Science and Technology, 24,57-74
Journal of Glaciology and Geocrylogy, 10(1), 8-14.
Journal of Glaciology and Geocrylogy, 24(2), 121-128.
Journal of Glaciology and Geocrylogy, 24(6), 759-764.
Cold Regions Science and Technology, 53(3), 346-354
Journal of Glaciology and Geocrylogy, 10(1), 8-14.
Journal of Glaciology and Geocrylogy, 24(2), 121-128.
Journal of Glaciology and Geocrylogy, 24(6), 759-764.
Cold Regions Science and Technology, 53(3), 346-354
Online since: January 2021
Authors: T. G. Sachidhananda, V. Adake Chandrashekhar
Journal of Materials Processing Technology 149, 272–277
Journal of Materials Processing Technology, 149 (1-3), 393
Journal of Materials Science, Volume 44, Issue 8, 1934-1951
Journal of Materials Processing Technology, 140, (1), 243
Journal of Materials Processing Technology, 140, 303
Journal of Materials Processing Technology, 149 (1-3), 393
Journal of Materials Science, Volume 44, Issue 8, 1934-1951
Journal of Materials Processing Technology, 140, (1), 243
Journal of Materials Processing Technology, 140, 303