Sort by:
Publication Type:
Open access:
Publication Date:
Periodicals:
Search results
Online since: October 2013
Authors: Ján Duplák, Matúš Čuma, Miroslav Kormoš
The main part of Standard ISO 3685 is T-vc dependence for various cutting materials.
In technical sciences are descriptions for each experiment, realization of process or adequate choice of cutting tools, materials, technological conditions, cutting parameters and theirs application.
Fig. 6 Examples of used cutting plates References [1] A.Panda.et.all.,” Accompanying phenomena in the cutting zone machinability during turning of stainless steels.”, International Journal Machining and Machinability of Materials, INDERSCENCE Publisher, Switzerland.
In: International Journal of Surface Science and Engineering.
In: Advanced Materials Research.
In technical sciences are descriptions for each experiment, realization of process or adequate choice of cutting tools, materials, technological conditions, cutting parameters and theirs application.
Fig. 6 Examples of used cutting plates References [1] A.Panda.et.all.,” Accompanying phenomena in the cutting zone machinability during turning of stainless steels.”, International Journal Machining and Machinability of Materials, INDERSCENCE Publisher, Switzerland.
In: International Journal of Surface Science and Engineering.
In: Advanced Materials Research.
Online since: December 2022
Authors: Shao Min Zhu, Yu Bin Yang, Hong Feng Xu
SC electrode materials mainly include carbon materials, conductive polymers, metal oxide/hydroxide, [6] etc.
Journal of Materials Chemistry A, 7, PP: 16028-16045, 2019. https://doi.org/10.1039/C9TA04436A [2] Wang G, Zhang L, Zhang J.
Journal of Materials Science and Chemical Engineering, 8, PP: 35-43, 2020. https://doi.org/10.4236/msce.2020.81004 [9] Lu Z, Xu W, Zhu W, Yang Q, Lei X, Liu J, Li Y, Sun X, Duan X.
Journal of Materials Chemistry, 20, PP: 7135-7143, 2010. https://doi.org/10.1039/C0JM00744G [12] Chiu K L, Lin L Y.
Journal of Materials Chemistry A, 7, PP: 4626-4639, 2019. https://doi.org/10.1039/c8ta11471d [13] Huang G, Zhang W, Xu S, Li Y, Yang Y.
Journal of Materials Chemistry A, 7, PP: 16028-16045, 2019. https://doi.org/10.1039/C9TA04436A [2] Wang G, Zhang L, Zhang J.
Journal of Materials Science and Chemical Engineering, 8, PP: 35-43, 2020. https://doi.org/10.4236/msce.2020.81004 [9] Lu Z, Xu W, Zhu W, Yang Q, Lei X, Liu J, Li Y, Sun X, Duan X.
Journal of Materials Chemistry, 20, PP: 7135-7143, 2010. https://doi.org/10.1039/C0JM00744G [12] Chiu K L, Lin L Y.
Journal of Materials Chemistry A, 7, PP: 4626-4639, 2019. https://doi.org/10.1039/c8ta11471d [13] Huang G, Zhang W, Xu S, Li Y, Yang Y.
Online since: January 2012
Authors: Xue Wei, Li Ming Feng, Yan Liu
Electrode materials determine directly the performance of battery.
The current researches of anode materials for lithium-ion batteries focus mainly on carbon materials, alloys, metal and non-metallic oxides, silicon materials etc[1-6].Carbon materials include graphite, carbon fiber, mesophase carbon microbead(MCMB)etc.
Electrochemical properties of tin-nickel-graphite composite anode materials.
Journal of Hunan Agricultural University (Natural Sciences). 2009, 35(1): 122-126 [7]A.
Journal of Material Science. 2007, 42(10): 3358–3366
The current researches of anode materials for lithium-ion batteries focus mainly on carbon materials, alloys, metal and non-metallic oxides, silicon materials etc[1-6].Carbon materials include graphite, carbon fiber, mesophase carbon microbead(MCMB)etc.
Electrochemical properties of tin-nickel-graphite composite anode materials.
Journal of Hunan Agricultural University (Natural Sciences). 2009, 35(1): 122-126 [7]A.
Journal of Material Science. 2007, 42(10): 3358–3366
Online since: July 2008
Authors: S. Quinn, Janice M. Dulieu-Barton, S. Sambasivam, R.K. Frühmann
Quinn
d
School of Engineering Sciences, University of Southampton, Southampton SO17 1BJ, UK
a
rkf@soton.ac.uk, bsshamala@soton.ac.uk, cjanice@soton.ac.uk, ds.quinn@soton.ac.uk
Keywords: Thermoelastic stress analysis (TSA), composite materials, strain witness
Abstract.
Stanley: Journal of Strain Analysis Vol. 33 (1998), p. 93
Chan: Journal of Strain Analysis Vol. 23 (1988), p. 137
Patterson: Composites Science and Technology Vol. 65 (2005), p. 269
Assche: J of Composite Materials Vol. 38 (2004), p. 163
Stanley: Journal of Strain Analysis Vol. 33 (1998), p. 93
Chan: Journal of Strain Analysis Vol. 23 (1988), p. 137
Patterson: Composites Science and Technology Vol. 65 (2005), p. 269
Assche: J of Composite Materials Vol. 38 (2004), p. 163
Online since: July 2011
Authors: Yu Cheng Wu, Guang Qing Xu, Dong Mei Wang, Zhi Xiang Zheng, Ling Kun Guo, Jun Lv, Song Zhou
Journal of Functional Materials, 2008,(39):1850-1852
Journal of Inorganic Materials,1997, 12(3):445-449
Journal of Inorganic Materials, 2000, 15(6):992-997 [19] Gao Liao, et al.
Journal of Inorganic Materials,1995,10(4):423-427
Journal of Functional Materials, 2008, 36(3):326-329
Journal of Inorganic Materials,1997, 12(3):445-449
Journal of Inorganic Materials, 2000, 15(6):992-997 [19] Gao Liao, et al.
Journal of Inorganic Materials,1995,10(4):423-427
Journal of Functional Materials, 2008, 36(3):326-329
Online since: October 2006
Authors: Kurosch Rezwan, Ludwig J. Gauckler
The protein adsorption process is of great interest in order to understand better the biointegration of implant
materials, with the long-term objective of synthesizing either fully biocompatible
materials or, in the ideal case, truly bio-active materials to replace current
materials.
However, cell adhesion, again, is dependent on protein adhesion on materials and protein interactions with materials.
Nose: Journal of Biomedical Materials Research Vol. 40 (1998), p. 24-30 [4] D.
Rouwendal: Journal of Colloid and Interface Science Vol. 139 (1990), p
Muller: Journal of Biomedical Materials Research Vol. 39 (1998), p. 478-485 [24] B.
However, cell adhesion, again, is dependent on protein adhesion on materials and protein interactions with materials.
Nose: Journal of Biomedical Materials Research Vol. 40 (1998), p. 24-30 [4] D.
Rouwendal: Journal of Colloid and Interface Science Vol. 139 (1990), p
Muller: Journal of Biomedical Materials Research Vol. 39 (1998), p. 478-485 [24] B.
Online since: May 2012
Authors: Zhao Jun Tian, Xue Liang Li
Injecting fire prevention materials.
Gel materials.
Materials of high water (or plaster).
Journal of CUMT Mining Science and Technology, 2004, 33(2):205-208
Journal of North China Institute of Science & Technology, 2002,4(2):8-10
Gel materials.
Materials of high water (or plaster).
Journal of CUMT Mining Science and Technology, 2004, 33(2):205-208
Journal of North China Institute of Science & Technology, 2002,4(2):8-10
Online since: October 2013
Authors: Jia Li Xu, Wen Hai Gai, Ran Guo
As a new type of composite material, particle reinforced composite materials, which has good mechanical properties and secondary machining, have been widely used in mechanical, biological, aerospace, military, motor and other important industrial areas.
This paper, based on the VCFEM, lead in the traditional FEM to research particle reinforced composite materials, tending to get a better result in simulating the mechanical property.
At the same time also verified the accuracy of the programming provides a new effective feasible computational method for the research of particles reinforced materials.
Elastic-plastic analysis of arbitrary heterogeneous materials with the Voronoi-cell finite-element method.
International Journal for Numerical Methods in Engineering, 1969, 1: 3~28 [4] Li Zailiang.
This paper, based on the VCFEM, lead in the traditional FEM to research particle reinforced composite materials, tending to get a better result in simulating the mechanical property.
At the same time also verified the accuracy of the programming provides a new effective feasible computational method for the research of particles reinforced materials.
Elastic-plastic analysis of arbitrary heterogeneous materials with the Voronoi-cell finite-element method.
International Journal for Numerical Methods in Engineering, 1969, 1: 3~28 [4] Li Zailiang.
Online since: August 2016
Authors: Winfried Malorny, Krzysztof Rokosz, Tadeusz Hryniewicz
Malorny, SEM and EDS analysis of NITINOL surfaces treated by Plasma Electrolytic Oxidation, Advances in Materials Science, 15(3;45) (2015) 41-47
Rokosz, Polarization characteristics of magnetoelectropolishing stainless steels, Materials Chemistry and Physics, 122(1) (2010) 169–174
Rokosz, Corrosion resistance of magnetoelectropolished AISI 316L SS biomaterial, Anti-Corrosion Methods and Materials, 61(2) (2014) 57–64
Rokicki, Effect of magnetoelectropolishing on nanohardness and Young’s modulus of titanium biomaterial, Materials Letters, 83 (2012) 69–72
Ooi, Antibacterial efficacy andcytotoxicity studies of copper (II) and titanium (IV) substituted hydroxyapatite nanoparticles, Materials Science and Engineering C, 30(8) (2010) 1137–1144
Rokosz, Polarization characteristics of magnetoelectropolishing stainless steels, Materials Chemistry and Physics, 122(1) (2010) 169–174
Rokosz, Corrosion resistance of magnetoelectropolished AISI 316L SS biomaterial, Anti-Corrosion Methods and Materials, 61(2) (2014) 57–64
Rokicki, Effect of magnetoelectropolishing on nanohardness and Young’s modulus of titanium biomaterial, Materials Letters, 83 (2012) 69–72
Ooi, Antibacterial efficacy andcytotoxicity studies of copper (II) and titanium (IV) substituted hydroxyapatite nanoparticles, Materials Science and Engineering C, 30(8) (2010) 1137–1144
Online since: January 2007
Authors: Joo Yung Jung, Gyeong Rak Choi, Jong Won Lee, In Pil Kang, Kwang Joon Yoon, Mark J. Schulz, Hyung Ki Park, Yeo Heung Yun, Vesselin N. Shanov
To address the need for new smart materials, this paper explores the use of carbon
nanotubes to develop a nanocomposite smart material having electrochemical impedance properties
for sensing and actuation.
Introduction Present smart materials and structures have fundamental limitations in their sensitivity, size, cost, ruggedness, and weight.
A new approach to develop smart structures is to develop intelligent electronic materials based on a conductive polymer matrix and carbon nanotubes.
Fabrication of Smart Nanoomposites Because of the CNTs small size and high surface area, fabricating functional macro scale materials has been a major challenge for applications such as high capacity energy storage, sensor materials, and electrochemical actuators.
Lockwood: Journal of Dispersion Science and Technology Vol. 23-1(2003), p. 1 24. 8.
Introduction Present smart materials and structures have fundamental limitations in their sensitivity, size, cost, ruggedness, and weight.
A new approach to develop smart structures is to develop intelligent electronic materials based on a conductive polymer matrix and carbon nanotubes.
Fabrication of Smart Nanoomposites Because of the CNTs small size and high surface area, fabricating functional macro scale materials has been a major challenge for applications such as high capacity energy storage, sensor materials, and electrochemical actuators.
Lockwood: Journal of Dispersion Science and Technology Vol. 23-1(2003), p. 1 24. 8.