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Online since: September 2024
Authors: Artem Ruban, Viktoriya Pasternak, Sergii Vavreniuk, Yurii Horbachenko
Journal of Materials Research and Technology. 9 (2020) 13937–13944
Materials Science Forum. 1006 (2020) 55–61
Journal of Materials Research and Technology. 9 (2020) 9232–9241
Journal of materials research and technology. 9 (2020) 15360–15380
Materials Science Forum. 1006 (2020) 47–54
Materials Science Forum. 1006 (2020) 55–61
Journal of Materials Research and Technology. 9 (2020) 9232–9241
Journal of materials research and technology. 9 (2020) 15360–15380
Materials Science Forum. 1006 (2020) 47–54
Online since: September 2011
Authors: Cui Ying Zhou, Zhen Liu
[9] Sheng Zhang, Hongbo Hen, Fei Wang, Journal of Hefei University of Technology(Natural Science). 30 (5) (2007) 611-615
[12] Chapman.D,Ahn.S,Hunt.D, Canadian Geotechnical Journal. 44 (6) (2007) 631-643
[15] Honggang An, Xiangdong Hu, Journal of Tongji University. 32 (12) (2004) 1573-1577
[19] Aizhong Lv, Chinese Journal Of Rock Mechanics And Engineering. 15 (3) (1996) 275-281
[21] Guangyi Sun, Yundong Ma, Journal of Heilongjiang Institute of Science and Technology. 17 (3) (2007) 169-172
[12] Chapman.D,Ahn.S,Hunt.D, Canadian Geotechnical Journal. 44 (6) (2007) 631-643
[15] Honggang An, Xiangdong Hu, Journal of Tongji University. 32 (12) (2004) 1573-1577
[19] Aizhong Lv, Chinese Journal Of Rock Mechanics And Engineering. 15 (3) (1996) 275-281
[21] Guangyi Sun, Yundong Ma, Journal of Heilongjiang Institute of Science and Technology. 17 (3) (2007) 169-172
Online since: August 2017
Authors: Chen Yuan Chung
Horgan, Saint-Venant end effects in composites, Journal of Composite Materials. 16 (1982) 411-422
Dimitrievska et al , Novel carbon fiber composite for hip replacement with improved in vitro and in vivo osseointegration, Journal of Biomedical Materials Research Part A. 91A (2009) 37-51
Hacking et al, Tissue response to the components of a hydroxyapatite-coated composite femoral implant, Journal of Biomedical Materials Research Part A. 94A (2010) 953-960
Benveniste, A new approach to the application of Mori-Tanaka’s theory in composite materials, Mechanics of Materials. 6 (1987) 147-157
Tjong, Structural and mechanical properties of polymer nanocomposites, Materials Science and Engineering: R: Reports. 53 (2006) 73-197.
Dimitrievska et al , Novel carbon fiber composite for hip replacement with improved in vitro and in vivo osseointegration, Journal of Biomedical Materials Research Part A. 91A (2009) 37-51
Hacking et al, Tissue response to the components of a hydroxyapatite-coated composite femoral implant, Journal of Biomedical Materials Research Part A. 94A (2010) 953-960
Benveniste, A new approach to the application of Mori-Tanaka’s theory in composite materials, Mechanics of Materials. 6 (1987) 147-157
Tjong, Structural and mechanical properties of polymer nanocomposites, Materials Science and Engineering: R: Reports. 53 (2006) 73-197.
Online since: January 2012
Authors: Zi Yu Zhao, Bi Bo Xia, Jin Guo Yang
The heating technology is a method for machining hard-to-machine materials economic and efficient [1].
Studies have shown that thermal expansion takes place in internal particles of hard and brittle materials by concentrated heating.
Thermally enhanced machining of hard-to-machine materials-A review.
Thermally enhanced machining of hard-to-machine materials-A review.
An experimental investigation of hot-machining to predict tool life. journal of materials processing technology. 198 (2008) 344–349
Studies have shown that thermal expansion takes place in internal particles of hard and brittle materials by concentrated heating.
Thermally enhanced machining of hard-to-machine materials-A review.
Thermally enhanced machining of hard-to-machine materials-A review.
An experimental investigation of hot-machining to predict tool life. journal of materials processing technology. 198 (2008) 344–349
Online since: May 2015
Authors: Wen Wei Yao
Introduction
Dosimeter materials for ionizing radiation have been widely used in the fields of radiation detection, environmental monitoring, medical diagnosis, deep space exploration[1-6].The thermoluminescence (referred to as TL) of material refers to thermal luminescence after the absorption of radiant energy[7].
Therefore, the characteristics of materials can be expressed by the curves of luminous intensity with temperature.
Acknowledgements This work was financially supported by the Natural Science Foundation of China (11474191) and the Educational Reform Foundation of Shaanxi Xueqian Normal University of China (14JG028Y).
Kim, Recent developments of Optically stimulated luminescence materials and techniques for radiation and clinical applications, Journal of Material Physics. 33 (2008) 85-89
Zhao, Effect of Fe and Cu Dopant and Annealing on the Growth and Spectral Properties of YAP Crystals,Journal of Inorganic Materials. 25 (2010) 102-1028
Therefore, the characteristics of materials can be expressed by the curves of luminous intensity with temperature.
Acknowledgements This work was financially supported by the Natural Science Foundation of China (11474191) and the Educational Reform Foundation of Shaanxi Xueqian Normal University of China (14JG028Y).
Kim, Recent developments of Optically stimulated luminescence materials and techniques for radiation and clinical applications, Journal of Material Physics. 33 (2008) 85-89
Zhao, Effect of Fe and Cu Dopant and Annealing on the Growth and Spectral Properties of YAP Crystals,Journal of Inorganic Materials. 25 (2010) 102-1028
Online since: December 2013
Authors: Dong Li, Da-Wei Luan, Zhen-Fang Wang, Tao Ma
As a strategic function material, GMM is considered to be important to the overall competitive power of national high science and technology in the 21st.
Nonlinear constitutive relations for magnetostrictive materials , Inier.
Mechanical Sciences, 43(2001) 2699-2713
Journal of Materials Processing Technology, 196(2008) 79-87
International Journal of Mechanical Sciences, 43(2001) 1711-1730.
Nonlinear constitutive relations for magnetostrictive materials , Inier.
Mechanical Sciences, 43(2001) 2699-2713
Journal of Materials Processing Technology, 196(2008) 79-87
International Journal of Mechanical Sciences, 43(2001) 1711-1730.
Online since: July 2008
Authors: Emad A. Badawi, Yahia A. Lotfy, M. Abdel-Rahman, M.A. Abdel-Rahman
Badawi*
Physics Department, Faculty of Science,
El-Minia University, Egypt
*e-mail : emadbadawi@yahoo.com
Keywords: Positron Annihilation Spectroscopy; Doppler broadening line-shape
parameters; AlCu alloys; Trapping rate; Grain size
Abstract
Positron Annihilation Spectroscopy (PAS) is a powerful and versatile tool for the
study of the microscopic structure of materials.
PAS is one of the sensitive non-destructive nuclear techniques used in material science.
Positron lifetime spectroscopy is based on the fact that positron annihilation is proportional to the electronic density at the annihilation site and so it can provide information about the electronic densities in materials.
References: [1] I.K.Mackenzie, T.L.Khoo, A.B.McDonald and B.T.A.McKee: Physical Review Letters, 19 (1967) 946 [2] P.Hautojärvi: Positrons in Solids, Topics in Current Physics, Springer-Verlag (1979) [3] C.Dauwe, M.Dorikens, L.Dorikens-Vanpraet and D.Segers: Applied Physics, 5 (1974) 117 [4] A.Dupasquier and A.P.Mills: Positron Spectroscopy of Solids, IOS Press (1995) [5] I.Procházka: Materials Structure, 8[2] (2001) 55 [6] J.M.Campillo Robles, E.Ogando and F.Plazaola: Journal of Physics - Condensed Matter, 19 (2007) 176222 [7] I.K.Mackenzie, J.A.Eady and R.R.Gingerich: Physics Letters A, 33 (1970) 279 [8] P.Asoka-Kumar, K.G.Lynn and D.O.Welch: Journal of Applied Physics, 76 (1994) 4935 [9] J.Dekker and K.Saarinen: Applied Physics Letters, 82[13] (2003) 2020 [10] M.Lech-Grega, S.Boczkal, J.Senderski and B.Plonka: Solid State Phenomena, 114 (2006) 165 [11] S.S.Kang, J.M.Dobois: Philosophical Magazine A, 66[1] (1992) 151 [12] M.S.Soliman: Journal of Materials
Science, 28 (1993) 4483 [13] J.L.Murray: International Metallurgical Reviews, 30 (1985) 211 [14] http://www.ifj.edu.pl/~mdryzek [15] K.Saarinen, T.Laine, S.Kuisma, J.Nissilä, P.Hautojärvi, L.Dobrzynski, J.M.Baranowski, K.Pakula, R.Stepniewski, M.Wojdak, A.Wysmolek, T.Suski, M.Leszczynski, I.Grzegory and S.Porowski: Physical Review Letters, 79[16] (1997) 3030 [16] A.Osipowicz, M.Harting, M.Hempel, D.T.Britton, W.Bauer-Kugelmann, W.Triftshauser: Applied Surface Science, 149 (1999) 198 [17] R.Krause-Rehberg and H.S.Leipner: Positron Annihilation in Semiconductors, Defect Studies, Springer (1999) [18] C.Hidalgo and N.de Diego: Applied Physics A, 27 (1982) 150 [19] T.E.M.Staab: Journal of Materials Science, 34 (1999) 3833
PAS is one of the sensitive non-destructive nuclear techniques used in material science.
Positron lifetime spectroscopy is based on the fact that positron annihilation is proportional to the electronic density at the annihilation site and so it can provide information about the electronic densities in materials.
References: [1] I.K.Mackenzie, T.L.Khoo, A.B.McDonald and B.T.A.McKee: Physical Review Letters, 19 (1967) 946 [2] P.Hautojärvi: Positrons in Solids, Topics in Current Physics, Springer-Verlag (1979) [3] C.Dauwe, M.Dorikens, L.Dorikens-Vanpraet and D.Segers: Applied Physics, 5 (1974) 117 [4] A.Dupasquier and A.P.Mills: Positron Spectroscopy of Solids, IOS Press (1995) [5] I.Procházka: Materials Structure, 8[2] (2001) 55 [6] J.M.Campillo Robles, E.Ogando and F.Plazaola: Journal of Physics - Condensed Matter, 19 (2007) 176222 [7] I.K.Mackenzie, J.A.Eady and R.R.Gingerich: Physics Letters A, 33 (1970) 279 [8] P.Asoka-Kumar, K.G.Lynn and D.O.Welch: Journal of Applied Physics, 76 (1994) 4935 [9] J.Dekker and K.Saarinen: Applied Physics Letters, 82[13] (2003) 2020 [10] M.Lech-Grega, S.Boczkal, J.Senderski and B.Plonka: Solid State Phenomena, 114 (2006) 165 [11] S.S.Kang, J.M.Dobois: Philosophical Magazine A, 66[1] (1992) 151 [12] M.S.Soliman: Journal of Materials
Science, 28 (1993) 4483 [13] J.L.Murray: International Metallurgical Reviews, 30 (1985) 211 [14] http://www.ifj.edu.pl/~mdryzek [15] K.Saarinen, T.Laine, S.Kuisma, J.Nissilä, P.Hautojärvi, L.Dobrzynski, J.M.Baranowski, K.Pakula, R.Stepniewski, M.Wojdak, A.Wysmolek, T.Suski, M.Leszczynski, I.Grzegory and S.Porowski: Physical Review Letters, 79[16] (1997) 3030 [16] A.Osipowicz, M.Harting, M.Hempel, D.T.Britton, W.Bauer-Kugelmann, W.Triftshauser: Applied Surface Science, 149 (1999) 198 [17] R.Krause-Rehberg and H.S.Leipner: Positron Annihilation in Semiconductors, Defect Studies, Springer (1999) [18] C.Hidalgo and N.de Diego: Applied Physics A, 27 (1982) 150 [19] T.E.M.Staab: Journal of Materials Science, 34 (1999) 3833
Online since: March 2017
Authors: Hui Jun Ren, G.Q. Tan, Ao Xia, Chi Xu, Cheng Cheng Zhao, Wei Yang
The bamboo-like FeVO4 nanocrystallines were synthesized by a two-step method of the microwave hydrothermal-calcination, using Fe(NO3)3·9H2O and NH4VO3 as raw materials.
As a new member of the vanadate photocatalytic materials family, FeVO4 has been found to have the catalytic capacity of oxidizing hydrocarbon [15].
Conclusions Using Fe(NO3)3·9H2O and NH4VO3 as raw materials, the bamboo-like triclinic FeVO4 nanocrystal is synthesized with microwave hydrothermal-calcination method.
Nano-photocatalytic Materials: Possibilities and Challenges [J].
Materials Research Bulletin, 46(10) (2011) 1654-1658
As a new member of the vanadate photocatalytic materials family, FeVO4 has been found to have the catalytic capacity of oxidizing hydrocarbon [15].
Conclusions Using Fe(NO3)3·9H2O and NH4VO3 as raw materials, the bamboo-like triclinic FeVO4 nanocrystal is synthesized with microwave hydrothermal-calcination method.
Nano-photocatalytic Materials: Possibilities and Challenges [J].
Materials Research Bulletin, 46(10) (2011) 1654-1658
Online since: October 2014
Authors: Ji Lin He, Dong Li, Yao Tan, Lei Xu, Yun Rong Ma
Journal of Composite Materials, 1993,27(3): 216-250
Journal of Composite Materials, 2001, 35(10): 826-849
Journal of Composite Materials, 1992, 26(5):626-660
Journal of Composite Materials, 1983, 17(2): 135-169
Journal of Composite Materials, 1992, 26(1): 132-149
Journal of Composite Materials, 2001, 35(10): 826-849
Journal of Composite Materials, 1992, 26(5):626-660
Journal of Composite Materials, 1983, 17(2): 135-169
Journal of Composite Materials, 1992, 26(1): 132-149