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Online since: October 2011
Authors: Jian Yun Li, Quan Xian Hua, Jun Ling Niu, Jian Wei Tang, Ke Xu
Materials and methods
Adsorbent
Steel slag was collected from a certain steel-making plant in China.
Lgwe, Afican Journal of Biotechnology, 6 (2005) 509-512
Zhang, Journal of Hazardous Materials, 153(2008) 300-308
Zhu, Journal of Hazardous Materials, 162 (2009) 391-401
Yang, et al, Journal of Hazardous Materials, 173 (2010) 558-562
Lgwe, Afican Journal of Biotechnology, 6 (2005) 509-512
Zhang, Journal of Hazardous Materials, 153(2008) 300-308
Zhu, Journal of Hazardous Materials, 162 (2009) 391-401
Yang, et al, Journal of Hazardous Materials, 173 (2010) 558-562
Online since: January 2009
Authors: Y. Watanabe, Hitoshi Ohmori, T. Mishima, H. Kasuga
Mishima1, d
1
Graduate School of Science and Engineering Saitama University, Saitama, Japan
2
Materials Fabrication Laboratory, RIKEN, Saitama, Japan
3
RILAC Team, RIKEN, Saitama, Japan
a
kasuga@me.ics.saitama-u.ac.jp; bohmori@mfl.ne.jp; cwatanabe@nano.gr.jp;
d
takemi@mail.saitama-u.ac.jp
Keywords: Dental ceramics, Hard and brittle material, Surface characteristics, ELID-Grinding
Abstract.
Progress of new dental materials such as biocompatible metal, ceramics is being accelerated because of aging society and sophistication of medical treatment.
So, development of new dental materials such as biocompatible metal, ceramics is being accelerated because those materials are physically stable and hardly have harmful effect to human body.
In the case of materials for the dental implant treatment, fixtures are made of a biocompatible metal such as titanium, titanium alloy.
On the other hand, the coping made of dental ceramics does not cause metal allergy and has better translucency, but some ceramic materials have lower strength than biocompatible metal.
Progress of new dental materials such as biocompatible metal, ceramics is being accelerated because of aging society and sophistication of medical treatment.
So, development of new dental materials such as biocompatible metal, ceramics is being accelerated because those materials are physically stable and hardly have harmful effect to human body.
In the case of materials for the dental implant treatment, fixtures are made of a biocompatible metal such as titanium, titanium alloy.
On the other hand, the coping made of dental ceramics does not cause metal allergy and has better translucency, but some ceramic materials have lower strength than biocompatible metal.
Online since: October 2014
Authors: Kamonrat Thamphueak, Oraporn Bualuang
Material and Methods
Raw Material: Sweet corn was purchased from Suratthani Farmer Supply in Suratthani province, Thailand.
The void fraction equations can be used to predict void fraction of seeds resulting from air flows through the materials in the drying chamber.
During the drying process, shrinkage of samples occurred because water into the food materials was removed.
Anand: Journal of Food Science and Technology-Mysore Vol. 46(6)(2009), p.591–594 [3] A.M.
Park: Journal of Cereal Science Vol. 59(2014), p.167-172 [14] S.H.
The void fraction equations can be used to predict void fraction of seeds resulting from air flows through the materials in the drying chamber.
During the drying process, shrinkage of samples occurred because water into the food materials was removed.
Anand: Journal of Food Science and Technology-Mysore Vol. 46(6)(2009), p.591–594 [3] A.M.
Park: Journal of Cereal Science Vol. 59(2014), p.167-172 [14] S.H.
Online since: February 2014
Authors: Manja Kitek Kuzman, Srečko Vratuša, Petra Grošelj
Sustainability also governs decisions concerning building materials.
Embodied energy in building materials represents the non-renewable energy consumed in the acquisition of raw materials, their processing, manufacturing, transportation to site, and construction – it represents the relationship between building materials, construction processes, and their environmental impacts.
Acknowledgements This study was a part of the Research Program “Wood and lignocellulosic materials” supported by the Ministry of Higher Education, Science and Technology of the Republic of Slovenia.
[5] Joseph, P., Tretsiakova-McNally, S.: Sustainable Non-Metallic Building Materials.
World Applied Sciences Journal 3(4): 609-613, (2008)
Embodied energy in building materials represents the non-renewable energy consumed in the acquisition of raw materials, their processing, manufacturing, transportation to site, and construction – it represents the relationship between building materials, construction processes, and their environmental impacts.
Acknowledgements This study was a part of the Research Program “Wood and lignocellulosic materials” supported by the Ministry of Higher Education, Science and Technology of the Republic of Slovenia.
[5] Joseph, P., Tretsiakova-McNally, S.: Sustainable Non-Metallic Building Materials.
World Applied Sciences Journal 3(4): 609-613, (2008)
Online since: October 2010
Authors: Bin Tong, Zheng Guo, Zheng Li, Jin Liu
Tomohisa[4] et al put forward and experienced an
effective method, which was about the reinforcing treatment of the soil rich in water and organic
matters with the materials of concrete power, pulp slag, fly coal ash, volcanic ash soil and so on.
Experiments Materials and Chemicals Acrylic acid (Tianjin Bodi Chemical Co., Ltd.), & ammonium persulfate , purified; acrylamide (Beijing Chemical Reagent Company), & isopropanol, impurified.
Acknowledgments The project is supported by Construction Ministry of Science & Technology Project in 2006(Grant Nos 06-K7-5),2008 National Natural Science Fund Project(Grant Nos 20771004), 2008 Anhui research program face project(Grant Nos 08010202144) and Functional Polymer & Chemical Building Materials Innovation Group School of Materials & Chemical Engineering Anhui Institute of Architecture & Industry.
Sample name Blank soil sample WSP+soil sample CaO+WS P+soil sample CBRl=2.5[ mm%] 4.1 4.7 25 CBRl=5[mm %] 3.9 4.2 24.9 Sample name Blank soil sample WSP+ soil sample CaO+WSP+ soil sample Resilient modulus[Mpa] 53.4 66.8 195 References [1] FAN Henghui, GAO Jianen, WU Pute: Journal of Northwest Science Technology of University Agriculture Forest (Natural Science Edition) Vol. 34 (2006) , p.142 [2] WANG Yinmei, YANG Zhongcun, CHEN Wenwu, et al: Rock Mechanics and Engineering Vol. 24 (2005) , p.2556 [3] [3] TANG Xueqin, SONG Maolin, LIU Xiuzhen: Shanxi Science & Technology of Communications Vol. 174 (2005) , p. 44 [4] Tomohisa S, Sawa K, Naitoh N: Zairyo Journal of the Society of Materials Science Japan Vol. 44 (1995) , p. 1025 [5] LIU Jin, CHEN Xiaoming, ZHANG Fengjun, et al: Materials Science & Engineering Vol. 34 (2002) , p. 233 [6] Theca C: Mycological Research Vol. 106 (2002) , p. 935 [7] WANG Yimin, ZHANG Lijuan, CHEN
Yekai, et al: Journal of South China University of Technology(Natural Science Edition) Vol. 34 (2006) , p. 56 [8] WANG Yinhei, HAN Wenfeng, CHEN Wenwu: The Chinese Journal of Geological Hazard and Control Vol. 15 (2004) , p.79 [9] XIANG Wei , CUI Deshan , LIU Li: Earth Science-Journal of China University of Geosciences Vol. 32 (2007) , p. 401 [10] Hyun-Joon Kong, Stacy G.
Experiments Materials and Chemicals Acrylic acid (Tianjin Bodi Chemical Co., Ltd.), & ammonium persulfate , purified; acrylamide (Beijing Chemical Reagent Company), & isopropanol, impurified.
Acknowledgments The project is supported by Construction Ministry of Science & Technology Project in 2006(Grant Nos 06-K7-5),2008 National Natural Science Fund Project(Grant Nos 20771004), 2008 Anhui research program face project(Grant Nos 08010202144) and Functional Polymer & Chemical Building Materials Innovation Group School of Materials & Chemical Engineering Anhui Institute of Architecture & Industry.
Sample name Blank soil sample WSP+soil sample CaO+WS P+soil sample CBRl=2.5[ mm%] 4.1 4.7 25 CBRl=5[mm %] 3.9 4.2 24.9 Sample name Blank soil sample WSP+ soil sample CaO+WSP+ soil sample Resilient modulus[Mpa] 53.4 66.8 195 References [1] FAN Henghui, GAO Jianen, WU Pute: Journal of Northwest Science Technology of University Agriculture Forest (Natural Science Edition) Vol. 34 (2006) , p.142 [2] WANG Yinmei, YANG Zhongcun, CHEN Wenwu, et al: Rock Mechanics and Engineering Vol. 24 (2005) , p.2556 [3] [3] TANG Xueqin, SONG Maolin, LIU Xiuzhen: Shanxi Science & Technology of Communications Vol. 174 (2005) , p. 44 [4] Tomohisa S, Sawa K, Naitoh N: Zairyo Journal of the Society of Materials Science Japan Vol. 44 (1995) , p. 1025 [5] LIU Jin, CHEN Xiaoming, ZHANG Fengjun, et al: Materials Science & Engineering Vol. 34 (2002) , p. 233 [6] Theca C: Mycological Research Vol. 106 (2002) , p. 935 [7] WANG Yimin, ZHANG Lijuan, CHEN
Yekai, et al: Journal of South China University of Technology(Natural Science Edition) Vol. 34 (2006) , p. 56 [8] WANG Yinhei, HAN Wenfeng, CHEN Wenwu: The Chinese Journal of Geological Hazard and Control Vol. 15 (2004) , p.79 [9] XIANG Wei , CUI Deshan , LIU Li: Earth Science-Journal of China University of Geosciences Vol. 32 (2007) , p. 401 [10] Hyun-Joon Kong, Stacy G.
Online since: February 2012
Authors: Zhao Wang Xia, Yuan Yuan Fang
Parameters considered include damper geometry, particle material and particle size.
Particle Impact Damping, Journal of Sound and Vibration, Vol.233 (2000) No.4, pp.93 [2] M.Saeki.
Impact Damping with Granular Materials in a Horizontally Vibrating System, Journal of Sound and Vibration, Vol.251 (2002) No.1, pp.153 [3] Zhaowang Xia, Yingchun Shan, Xiandong Liu.
Experimental Research on Particle Damping of Cantilever Beam, Journal of Aerospace Power, Vol.22(2007) No.10, pp.1737 [4] S.
Structural damping enhancement via non-obstructive particle damping technique, Journal of Vibration and Acoustics, Vol.114(2007), pp.101 [6] H.
Particle Impact Damping, Journal of Sound and Vibration, Vol.233 (2000) No.4, pp.93 [2] M.Saeki.
Impact Damping with Granular Materials in a Horizontally Vibrating System, Journal of Sound and Vibration, Vol.251 (2002) No.1, pp.153 [3] Zhaowang Xia, Yingchun Shan, Xiandong Liu.
Experimental Research on Particle Damping of Cantilever Beam, Journal of Aerospace Power, Vol.22(2007) No.10, pp.1737 [4] S.
Structural damping enhancement via non-obstructive particle damping technique, Journal of Vibration and Acoustics, Vol.114(2007), pp.101 [6] H.
Online since: December 2012
Authors: Xiao Yan Luo, Wei Ping Liu
The formulas in the paper have significance in exerting material potential and save material.
Through numerous tests on rock, the existence of the intermediate principal stress effect has now been well recognized as characteristics of the materials [4] [5].
The theory is especially versatile in reflecting effect to different extents for different materials.
Shosuke, et al: Journal of Structural Engineering, Vol.130(2004), p.180-188
[7] Xiaorong Hu, Taiqing Lin:The Chinese Journal of Nonferrous Metals.Vol. 17(2007) ,p.207-215.
Through numerous tests on rock, the existence of the intermediate principal stress effect has now been well recognized as characteristics of the materials [4] [5].
The theory is especially versatile in reflecting effect to different extents for different materials.
Shosuke, et al: Journal of Structural Engineering, Vol.130(2004), p.180-188
[7] Xiaorong Hu, Taiqing Lin:The Chinese Journal of Nonferrous Metals.Vol. 17(2007) ,p.207-215.
Online since: June 2013
Authors: Liang Gong, Ai Xia Diao, Chang Xi Ma, Xiao Ning Zhao
The objective function of model is to minimize time delay meeting material need, and the constraints include vehicle balance constraints, traffic constraints, road capacity constraints, constraints of rescue materials supply point, demand constraints, and so on.
Therefore, the determination of temporary rescue path , rush repair and arrangement of damaged transportation routes and the facilities, timely rescue and transfer of afflicted personnel, timely allocation and service of disaster relief personnel, layout optimization of emergency logistics facilities, reserves control of emergency rescue materials, optimization scheduling of emergency rescue materials, and collaboration transportation plans of various transportation way are the eight key problems in optimization of emergency transportation and logistics system, and they are interdependence and interaction.
Socio-Economic Planning Sciences, Vol.27(1993),p.97-108
International Journal of Systems Science, Vol.27(1996),p.931-936
Journal of Natural Disaster, Vol.14(2005),p.131-135
Therefore, the determination of temporary rescue path , rush repair and arrangement of damaged transportation routes and the facilities, timely rescue and transfer of afflicted personnel, timely allocation and service of disaster relief personnel, layout optimization of emergency logistics facilities, reserves control of emergency rescue materials, optimization scheduling of emergency rescue materials, and collaboration transportation plans of various transportation way are the eight key problems in optimization of emergency transportation and logistics system, and they are interdependence and interaction.
Socio-Economic Planning Sciences, Vol.27(1993),p.97-108
International Journal of Systems Science, Vol.27(1996),p.931-936
Journal of Natural Disaster, Vol.14(2005),p.131-135
Ultrasonic Assisted Electro Deposition and Characterization of Ni–P Alloy onto Sintered NdFeB Magnet
Online since: May 2011
Authors: Li Li, Dong Wang, Fei Fei Wang, Zong Wei Niu
Forum Vol. 83-87 (1992), p. 119
[1] Bai G, Gao R W and Sun Y: Journal of Magnetism and Magnetic Materials Vol. 308 (2007), p. 20
[2] Vial F.
Ioly and Nevalainen E. : Journal of Magnetism and Magnetic Materials Vol.242-245 (2002), p.1329 [3] Gao R W.
Li W: Journal of Magnetism and Magnetic Materials Vol.208 (2000), p. 239 [4] Matsuura Yutaka: Journal of Magnetism and Magnetic Materials Vol. 303(2006.), p. 344 [5] Tattam C, Williams A J.
Hay J N.: Journal of Magnetism and Magnetic Materials Vol. 152(1996), p. 275 [6] Tamborim Takeuchi SM.
Yan M.: Journal of Magnetism and Magnetic Materials Vol. 283(2004.), p. 353 [8] Walton A.
Ioly and Nevalainen E. : Journal of Magnetism and Magnetic Materials Vol.242-245 (2002), p.1329 [3] Gao R W.
Li W: Journal of Magnetism and Magnetic Materials Vol.208 (2000), p. 239 [4] Matsuura Yutaka: Journal of Magnetism and Magnetic Materials Vol. 303(2006.), p. 344 [5] Tattam C, Williams A J.
Hay J N.: Journal of Magnetism and Magnetic Materials Vol. 152(1996), p. 275 [6] Tamborim Takeuchi SM.
Yan M.: Journal of Magnetism and Magnetic Materials Vol. 283(2004.), p. 353 [8] Walton A.
Online since: September 2013
Authors: Rahadi Wirawan, A. Waris, Gunawan Handayani, Hong Joo Kim, M. Djamal
The response function for gamma-ray detector depends on incoming photon energy, dimension and shape of detector, detector materials, and geometrical of irradiation conditions [5].
[3] Tao Chi, Dingsong Zhang: Response Function Test of Marine γ-spectrometry with Different Detector Material, Key Engineering Materials Vol. 500, Trans Tech Publications (2012), pp 108-113
Miri-Hakimabad: The Effect of Detector Dimensions on the NaI(Tl) Detector Response Function, Journal of Applied Sciences 9 (11) (2009), pp. 2168-2173
[9] Tao Chi, Dingsong Zhang: Response Function Test of Marine γ-spectrometry with Different Detector Material, Key Engineering Materials Vol. 500 (2012), pp. 108-113
A.: Determination of Full Energy Peak Efficiency of NaI(Tl) Detector Depending on Efficiency Transfer Principle for Conversion From Experimental Values, World Journal of Nuclear Science and Technology, (2012), pp. 65-72.
[3] Tao Chi, Dingsong Zhang: Response Function Test of Marine γ-spectrometry with Different Detector Material, Key Engineering Materials Vol. 500, Trans Tech Publications (2012), pp 108-113
Miri-Hakimabad: The Effect of Detector Dimensions on the NaI(Tl) Detector Response Function, Journal of Applied Sciences 9 (11) (2009), pp. 2168-2173
[9] Tao Chi, Dingsong Zhang: Response Function Test of Marine γ-spectrometry with Different Detector Material, Key Engineering Materials Vol. 500 (2012), pp. 108-113
A.: Determination of Full Energy Peak Efficiency of NaI(Tl) Detector Depending on Efficiency Transfer Principle for Conversion From Experimental Values, World Journal of Nuclear Science and Technology, (2012), pp. 65-72.