Sort by:
Publication Type:
Open access:
Publication Date:
Periodicals:
Search results
Online since: August 2007
Authors: Sang Shik Kim, Richard P. Gangloff, Jenifer S. Warner
Gangloff
1
1: Department of Materials Science and Engineering, University of Virginia, Charlottesville, Va
2: Division of Materials Science and Engineering, Gyeongsang National University, Chinju, Korea
jsw5e@virginia.edu, sang@gsnu.ac.kr, rpg7y@virginia.edu
Keywords: fatigue, sodium molybdate, chromate, hydrogen embrittlement, AA7075-T6
ABSTRACT
The objective of this study is to quantify and understand the effectiveness of a hexavalent chrome
replacement ion to inhibit environmentally assisted fatigue crack propagation (EFCP) in high strength
aluminum alloys.
Gangloff. in Fatigue '02, Anders Blom, ed., Engineering Materials Advisory Services, West Midlands, UK, pp. 3401-3433 (2002)
Corrosion Science. 45, pp. 1921-1938 (2003)
International Journal of Fatigue. 24, pp. 803-809 (2002)
Corrosion Science. 47, pp. 1227-1237 (2005)
Gangloff. in Fatigue '02, Anders Blom, ed., Engineering Materials Advisory Services, West Midlands, UK, pp. 3401-3433 (2002)
Corrosion Science. 45, pp. 1921-1938 (2003)
International Journal of Fatigue. 24, pp. 803-809 (2002)
Corrosion Science. 47, pp. 1227-1237 (2005)
Online since: September 2019
Authors: Cao Dang Le, Valeri Mikhailovich Golod, Konstanchin D. Savelyev
Vikhareva, Controlling behavior of δ-ferrite in nitrogen-containing chromium–nickel–manganese steels, Inorganic Materials: Applied Research, 8 (2017) 817-826
Saveliev, Computational thermodynamics in materials science, Saint-Petersburg, Russia, Publishing house, Polytechnic University, 2010
Dobosh, Computational materials science of structural - phase transformations in casting aluminum alloys, Int.
"Structural and Phase Transformations in Materials: Theory, Computer Modelling and Experiment", 23–27 March 2017, Ekaterinburg, Russia.
IOP Conference Series: Materials Science and Engineering, 192 (2017), 012027
Saveliev, Computational thermodynamics in materials science, Saint-Petersburg, Russia, Publishing house, Polytechnic University, 2010
Dobosh, Computational materials science of structural - phase transformations in casting aluminum alloys, Int.
"Structural and Phase Transformations in Materials: Theory, Computer Modelling and Experiment", 23–27 March 2017, Ekaterinburg, Russia.
IOP Conference Series: Materials Science and Engineering, 192 (2017), 012027
Online since: October 2012
Authors: Tao Min Wei, Jin Ping Li, Jun Ma, Qin Tong Zhao, Lei Lei Wang
Economical analysis on the system
Devoted operating costs
The devoted operating costs should include the cost of equipments, materials, and labors.
China: Kunming University of Science and Technology.(2005)
Science in China (E).
China: Jilin Science & Technology Press.1994,4
Journal of Liaoning Teachers College Vol.4(2002), P.84
China: Kunming University of Science and Technology.(2005)
Science in China (E).
China: Jilin Science & Technology Press.1994,4
Journal of Liaoning Teachers College Vol.4(2002), P.84
Online since: January 2006
Authors: Jia Jin Zheng, Xin Zhu Zhou, Shi Lang Xu
Bourdette: Advanced Cement Based Materials, Vol. 2 (1995), p.
30
Pigeon: Advanced Cement Based Materials, Vol. 5 (1997), p. 86
Bentz: Advanced Cement Based Materials, Vol. 6 (1997), p. 99
Bentz: Advanced Cement Based Materials, Vol. 2 (1995), p. 169
Zheng: Journal of Jishou University, Vol. 55 (2003), p. 27.
Pigeon: Advanced Cement Based Materials, Vol. 5 (1997), p. 86
Bentz: Advanced Cement Based Materials, Vol. 6 (1997), p. 99
Bentz: Advanced Cement Based Materials, Vol. 2 (1995), p. 169
Zheng: Journal of Jishou University, Vol. 55 (2003), p. 27.
Online since: February 2014
Authors: Florian Quantmeyer, Xiao Bo Liu-Henke
With lithium-ion cells there are a vast number of possible combinations of active materials for the electrodes.
Concerning cathode materials, [2] offers a comprehensive overview.
Table 1 displays the main characteristics of these cathode materials.
Table 1: Properties of different cathode materials for lithium-ion cells, taken from [1].
Whittingham, Lithium Batteries and Cathode Materials, Chemical Reviews 104 (2004), 4271-4301
Concerning cathode materials, [2] offers a comprehensive overview.
Table 1 displays the main characteristics of these cathode materials.
Table 1: Properties of different cathode materials for lithium-ion cells, taken from [1].
Whittingham, Lithium Batteries and Cathode Materials, Chemical Reviews 104 (2004), 4271-4301
Online since: March 2009
Authors: Andrea Ghiotti, Stefania Bruschi, Daniele Pellegrini, J. Lechler, Marion Merklein
While extensive studies [4-6] can be found in literature about
material characterization, few data are instead available on material formability [7-9].
Material The material employed in the testing is the boron-alloyes steel 22MnB5 (commercially known as Usibor 1500™), provided in sheets of 1.5 mm (DIMEG) and 1.75 mm (LFT) thickness.
Hein: Advanced Materials Research, Vol. 6-8 (2005) p. 763
Wagener: Journal of Materials Processing Technology, Vol. 72 (1007), p. 342
Merklein: Proc. of Material Science and Technology Conf. (2008), p. 1698.
Material The material employed in the testing is the boron-alloyes steel 22MnB5 (commercially known as Usibor 1500™), provided in sheets of 1.5 mm (DIMEG) and 1.75 mm (LFT) thickness.
Hein: Advanced Materials Research, Vol. 6-8 (2005) p. 763
Wagener: Journal of Materials Processing Technology, Vol. 72 (1007), p. 342
Merklein: Proc. of Material Science and Technology Conf. (2008), p. 1698.
Online since: May 2011
Authors: Xin Guang Peng, Yan Ru Feng, Min Li
Automated Trust Negotiation for Web Services
Peng Xinguang, Feng Yanru, and Li Min
Taiyuan University of Technology, College of Computer Science and Technology
Taiyuan, China
fengyanru05@163.com
Keywords: trusted computing, automated trust negotiation, modeling
Abstract.
Acknowledgment The authors would like to thank the projects supported by the Natural Science Foundation of Shanxi Province under Grant No. 2009011022-2; supported by Shanxi Scholarship Council of China Grant No. 2009-28.
[2] David Challener, Ken Yoder, in: A Practical Guide to Trusted Computing, edited by Greg Wiegand, volume 1 of Background Material, chapter, 3, Pearson plc Publishers (2007)
[4] Liao ZS, Jin H, Li CS, Zou DQ: Journal of Software, Vol.17 (2006), p. 1933-1948
[5] Geng Xiuhua, Han Zhen, Jin Li: Journal of Beijing Jiaotong University, Vol. 33 (2009), p. 11-16
Acknowledgment The authors would like to thank the projects supported by the Natural Science Foundation of Shanxi Province under Grant No. 2009011022-2; supported by Shanxi Scholarship Council of China Grant No. 2009-28.
[2] David Challener, Ken Yoder, in: A Practical Guide to Trusted Computing, edited by Greg Wiegand, volume 1 of Background Material, chapter, 3, Pearson plc Publishers (2007)
[4] Liao ZS, Jin H, Li CS, Zou DQ: Journal of Software, Vol.17 (2006), p. 1933-1948
[5] Geng Xiuhua, Han Zhen, Jin Li: Journal of Beijing Jiaotong University, Vol. 33 (2009), p. 11-16
Online since: February 2014
Authors: Yong Jun Hu
Ecological Civilization Construction in China:
Origins, Concepts and Paths
Yongjun Hu 1
Institute of Geographic Sciences and Natural Resources Research,Chinese Academy of Sciences,Beijing 100101,China;
hyjhyj18@126.com
Keywords: Concept, Ecological Civilization Construction, Origin, Path
Abstract.
Firstly, the propaganda and education of ecological civilization contributes to strengthen the awareness of ecological protection and the respect for nature law, and hence forms the environmental-friendly behaviors; different levels of planning can determine the whole layout, guide the development direction, control land use intensity and standardize the development order; institution innovations should happen in the fields of resource, environment, ecology and space management, including the improvement of laws and regulations, the integration of management services system and the establishment of the government assessment mechanism; increasing the investment for ecological protection helps to improve the ability of ecosystem services and guarantees environment quality; developing the ecological science and technology by the implementation of innovation project propels the transformation and application of science achievements about ecology and environment.
International Conference on Green Building, Materials and Civil Engineering (GBMCE 2011).2011 [4]MAO Ming-fang.
Journal of China Executive Leadership Academy Pudong.2010.4(5):92-96( in Chinese) [5] DU Ying.
Bulletin of Chinese Academy of Sciences.2012. 27(3):269-273( in Chinese) [6] SONG Xu-guang.
Firstly, the propaganda and education of ecological civilization contributes to strengthen the awareness of ecological protection and the respect for nature law, and hence forms the environmental-friendly behaviors; different levels of planning can determine the whole layout, guide the development direction, control land use intensity and standardize the development order; institution innovations should happen in the fields of resource, environment, ecology and space management, including the improvement of laws and regulations, the integration of management services system and the establishment of the government assessment mechanism; increasing the investment for ecological protection helps to improve the ability of ecosystem services and guarantees environment quality; developing the ecological science and technology by the implementation of innovation project propels the transformation and application of science achievements about ecology and environment.
International Conference on Green Building, Materials and Civil Engineering (GBMCE 2011).2011 [4]MAO Ming-fang.
Journal of China Executive Leadership Academy Pudong.2010.4(5):92-96( in Chinese) [5] DU Ying.
Bulletin of Chinese Academy of Sciences.2012. 27(3):269-273( in Chinese) [6] SONG Xu-guang.
Online since: May 2014
Authors: Liu Zhi Jiang, Xue Lei Wang, Xuan Ban
Influence of the Three Gorges Project on Water Level in the Middle Reaches of Yangtze River, China
Liuzhi Jiang1,2,a, Xuelei Wang1,3,b, Xuan Ban1,3,c
1Institute of Geodesy and Geophysics, Chinese Academy of Sciences, Wuhan, China;
2 University of Chinese Academy of Sciences, Beijing, China
3Hubei Key Laboratory of Environment and Disaster Monitoring and Evaluation, Wuhan, China
ajiangliuzhi.0622@163.com, bxueleiwang@whigg.ac.cn, cbanxuan@whigg.ac.cn
Keywords: Water level; Range of variability approach; Indicators of hydrologic alteration; Three Gorges Project; Yangtze River
Abstract.
Materials and method Data preparation Daily water level data from fivehydrological stations (i.e., Yichang, Jianli, Chenglingji, Luoshan andHankou stations) in the middle reaches of the Yangtze River were analyzed in this study (Figure. 1, Table 1).
Science, 2005, 308: 405–408
Science, 2003, 300: 1239–1240
Journal of Hydrology, 2006, 331: 511–523.
Materials and method Data preparation Daily water level data from fivehydrological stations (i.e., Yichang, Jianli, Chenglingji, Luoshan andHankou stations) in the middle reaches of the Yangtze River were analyzed in this study (Figure. 1, Table 1).
Science, 2005, 308: 405–408
Science, 2003, 300: 1239–1240
Journal of Hydrology, 2006, 331: 511–523.
Online since: August 2010
Authors: Shi Gang Wang, Xi Bing Li, Jian Hua Guo, Dong Sheng Li
Influenced by the
tiny pressure differential, vapor flows to condenser, emitting heat quantity, and changes into liquid;
then the liquid flows back to evaporator along the multi-hole material by the action of capillary
force.
Acknowledgement This work was supported by Heilongjiang Natural Science Foundation general program (Grant No.
References [1] Chen Deng-ke: Chinese Journal of Low Temperature Physics. 8(2005), p.255-262 [2] Vasiliev L.L.: Applied Thermal Engineering. 8(2006), p.105-113 [3] Zhuang Jun, Zhang Hong.
Thermal Sciences. 43(2004), p.499-507 [6] Sartre V., Zaghdoudi M.C., Lallemand M: Int.
Heat pipe science and technology.
Acknowledgement This work was supported by Heilongjiang Natural Science Foundation general program (Grant No.
References [1] Chen Deng-ke: Chinese Journal of Low Temperature Physics. 8(2005), p.255-262 [2] Vasiliev L.L.: Applied Thermal Engineering. 8(2006), p.105-113 [3] Zhuang Jun, Zhang Hong.
Thermal Sciences. 43(2004), p.499-507 [6] Sartre V., Zaghdoudi M.C., Lallemand M: Int.
Heat pipe science and technology.