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Online since: October 2021
Authors: Andrey Ponomarev, Ivan Kuznecov, Olga Malyugina, Nilufar Mamatmusaeva, Umida Tillaeva, Botir Daminov, Saida Saidkhodjaeva, Marat Iskandarov
Therefore, clinical materials science, among other things, studies the interaction of materials and the human body (a patient and a doctor).
These materials are called biocompatible.
Types of dental biocompatible materials: 1.
Journal of Traumatology and Orthopedics. 2003.
Osteoinductive molecules in orthopaedics // Basic science and clinical studies. 2002. № 395.
These materials are called biocompatible.
Types of dental biocompatible materials: 1.
Journal of Traumatology and Orthopedics. 2003.
Osteoinductive molecules in orthopaedics // Basic science and clinical studies. 2002. № 395.
Online since: August 2013
Authors: Hao Zhang, Ying Zhang, Yu Huan Zhang
With the greatly extended of the biodegradable polymeric materials’ application domain, the research of polymeric materials’ degradation process is getting more concerned.
Biodegradable polymeric materials degradation model is advanced under this background to simulate and forecast the polymeric materials’ degradation process, then overcome difficulties via computer-aided design.
Biodegradable Polymer Materials’ Degradation Model At present the study on polymer materials’ biodegradation process is focused on chemical hydrolysis of the polymer backbone.
Molecular degradation of polymer materials changes over degradation time.
Establishment of Parameters Optimization Model The degradation model of biodegradable polymer materials simulates the degradation process of polymer materials by computer and the simulation results should be consistent with the experimental data.
Biodegradable polymeric materials degradation model is advanced under this background to simulate and forecast the polymeric materials’ degradation process, then overcome difficulties via computer-aided design.
Biodegradable Polymer Materials’ Degradation Model At present the study on polymer materials’ biodegradation process is focused on chemical hydrolysis of the polymer backbone.
Molecular degradation of polymer materials changes over degradation time.
Establishment of Parameters Optimization Model The degradation model of biodegradable polymer materials simulates the degradation process of polymer materials by computer and the simulation results should be consistent with the experimental data.
Online since: December 2019
Authors: Valery Lesovik, Lilia H. Zagorodnyuk, E.S. Glagolev, A.A. Volodchenko
The theoretical basis for solving this urgent problem is the transdisciplinary science of geonics (geomimetics).
Volodchenko, Development composition of thermal insulation materials autoclave curing based on clay raw materials, Bulletin of BSTU named after V.G.
Nakhaev, Composite Binders with the Use of Fine Raw Materials of Volcanic Origin, International journal of environmental & science education. 11 (18) (2016) 12711-12716 [7] N.I.
Suleymanov, The influence of technological factors on the basic properties of vibropressed concrete paving slabs, Research Journal of Applied Sciences. 9 (11) (2014) 874-878 [9] A.A.
Zagorodnjuk, Improving the efficiency of wall materials for «green» building through the use of aluminosilicate raw materials, International Journal of Applied Engineering Research. 10 (24) (2015) 45142-45149
Volodchenko, Development composition of thermal insulation materials autoclave curing based on clay raw materials, Bulletin of BSTU named after V.G.
Nakhaev, Composite Binders with the Use of Fine Raw Materials of Volcanic Origin, International journal of environmental & science education. 11 (18) (2016) 12711-12716 [7] N.I.
Suleymanov, The influence of technological factors on the basic properties of vibropressed concrete paving slabs, Research Journal of Applied Sciences. 9 (11) (2014) 874-878 [9] A.A.
Zagorodnjuk, Improving the efficiency of wall materials for «green» building through the use of aluminosilicate raw materials, International Journal of Applied Engineering Research. 10 (24) (2015) 45142-45149
Online since: January 2012
Authors: Fei Wang, Qing Guo Tang, Jian Min Zhang
Main Thermal Insulation Materials
2.1 Obstructive insulation materials
The application of the composition of low thermal conductivity is a basic form of developing obstructive insulation materials.
Currently, inorganic mineral insulation materials were low cost and widely used in barrier insulation materials.
Hemberger: International Journal of Thermal Sciences, Vol. 50(2011), p. 1838 [9] M.
Du: International Journal of Thermal Sciences, Vol.48 (2009), p. 1302 [11] Z.J.
Ng: Materials Science and Engineering: B, Vol. 132(2006), p. 209 [21] M.A.
Currently, inorganic mineral insulation materials were low cost and widely used in barrier insulation materials.
Hemberger: International Journal of Thermal Sciences, Vol. 50(2011), p. 1838 [9] M.
Du: International Journal of Thermal Sciences, Vol.48 (2009), p. 1302 [11] Z.J.
Ng: Materials Science and Engineering: B, Vol. 132(2006), p. 209 [21] M.A.
Online since: January 2026
Authors: Ahmed S. Al-Chalabi, Areej K. Al-Jwaid, Jaaffer A. Mohammed
Planting groups with weight of added materials and seeds
No.
Fig. 5. pH values before and after adding materials.
EC measurements before and after adding materials.
Concentration of SO4 before and after adding materials.
Wittayakun, Synthesis and characterization of zeolite LSX from rice husk silica, Suranaree Journal of Science and Technology. 14 (2007) 367
Fig. 5. pH values before and after adding materials.
EC measurements before and after adding materials.
Concentration of SO4 before and after adding materials.
Wittayakun, Synthesis and characterization of zeolite LSX from rice husk silica, Suranaree Journal of Science and Technology. 14 (2007) 367
Online since: April 2015
Authors: Hsiu Lu Chiang, Tsu Liang Chou, Tze Chi Hsu, Jing Hong Chen
Surface roughness and magnetic effect of magnetized journal bearings lubricated with ferrofluid
Tze-Chi Hsu1, a, Jing-Hong Chen2, b, Tsu-Liang Chou3, Hsin-Lu Chiang3
1Department of Mechanical Engineering, Yuan-Ze Unversity, Chung-Li 320, Taiwan, ROC
2National Chung-Shan Institute of Science & Technology, P.O.
Ferrofluids are widely applied in bearing systems due to their unique characteristics possessing both the powerful magnetism of solid magnetic materials as well as the liquidity of fluids [1-4].
When λ<0.6, the surface roughness behavior of the journal bearing is similar to the short journal bearing.
When λ>1.8, the surface roughness behavior of the journal bearing is similar to the long journal bearing.
Journal of marine science and technology, Vol.22(2014), No. 2, p. 154-162
Ferrofluids are widely applied in bearing systems due to their unique characteristics possessing both the powerful magnetism of solid magnetic materials as well as the liquidity of fluids [1-4].
When λ<0.6, the surface roughness behavior of the journal bearing is similar to the short journal bearing.
When λ>1.8, the surface roughness behavior of the journal bearing is similar to the long journal bearing.
Journal of marine science and technology, Vol.22(2014), No. 2, p. 154-162
Online since: January 2010
Authors: Mustafa Koçak, Felix Beckmann, Peter Staron, Andreas Schreyer, Norbert Schell, Thomas Lippmann, Astrid Haibel, Lars Lottermoser, Julia Herzen, Torben Fischer
The New GKSS Materials Science Beamlines at DESY:
Recent Results and Future Options
P.
Introduction In engineering materials science X-ray scattering and micro-tomography using synchrotron radiation have over approximately the last 10 years evolved as an increasingly accepted and utilized technique for characterizing the internal structure of materials.
The new high-energy beamline HARWI II is dedicated to texture, strain, and imaging measurements for materials science (Fig. 1).
Synchrotron radiation based micro computed tomography (SRµCT) is an established imaging method in the field of materials science.
Thus, GKSS is offering a suite of beamlines and corresponding experimental environments with a strong focus on the engineering materials science community.
Introduction In engineering materials science X-ray scattering and micro-tomography using synchrotron radiation have over approximately the last 10 years evolved as an increasingly accepted and utilized technique for characterizing the internal structure of materials.
The new high-energy beamline HARWI II is dedicated to texture, strain, and imaging measurements for materials science (Fig. 1).
Synchrotron radiation based micro computed tomography (SRµCT) is an established imaging method in the field of materials science.
Thus, GKSS is offering a suite of beamlines and corresponding experimental environments with a strong focus on the engineering materials science community.
Online since: April 2022
Authors: Sravan Bokka, Srungarpu Nagabhusan Achary, Anirban Chowdhury
[3] Bajaj, P., Fire-retardant materials, Bulletin of Materials Science, 15 (1992) 67-76
Kumar, Structural, thermal, dielectric studies on sol–gel derived MgO from non-alkoxide route, Materials science and technology, 22 (2006) 1249-1254
Wilkie, Fire retardancy and morphology of layered double hydroxide nanocomposites: a review, Journal of Materials Chemistry, 22 (2012) 18701
[60] Maitra, S., et al., Effect of compaction on the kinetics of thermal decomposition of dolomite under non-isothermal condition, Journal of Materials Science, 40 (2005) 4749-4751
Levchik, A review of current flame retardant systems for epoxy resins, Journal of fire sciences, 22 (2004) 25-40
Kumar, Structural, thermal, dielectric studies on sol–gel derived MgO from non-alkoxide route, Materials science and technology, 22 (2006) 1249-1254
Wilkie, Fire retardancy and morphology of layered double hydroxide nanocomposites: a review, Journal of Materials Chemistry, 22 (2012) 18701
[60] Maitra, S., et al., Effect of compaction on the kinetics of thermal decomposition of dolomite under non-isothermal condition, Journal of Materials Science, 40 (2005) 4749-4751
Levchik, A review of current flame retardant systems for epoxy resins, Journal of fire sciences, 22 (2004) 25-40
Online since: January 2012
Authors: Ying Sun, Jia Lu Li, Xian Xin Li, Ming Ma
[9] Junjie Yao, Baoshun Li, Xiaoxian Huang et al.: Journal of Inorganic Materials Vol. 12(1997), p. 47-53, in Chinese
[10] Jiehua Wu, Baoshun Li, Cheng’en Li et al.: Journal of Basic Science and Engineering Vol. 8(2000), p. 38-43, in Chinese
[18] Caiyun Yang and Jialu Li: Journal of Donghua University, Natural Science Vol. 31(2005), p. 53-58, in Chinese
[20] Guojun Wang, Ying Sun, Binbin Shi et al.: Journal of Materials Engineering Vol. 2(2009), p. 332-335, in Chinese
[23] Chaokun Yang: Journal of Materials Engineering Vol. 7(2002), p. 33-39, in Chinese.
[10] Jiehua Wu, Baoshun Li, Cheng’en Li et al.: Journal of Basic Science and Engineering Vol. 8(2000), p. 38-43, in Chinese
[18] Caiyun Yang and Jialu Li: Journal of Donghua University, Natural Science Vol. 31(2005), p. 53-58, in Chinese
[20] Guojun Wang, Ying Sun, Binbin Shi et al.: Journal of Materials Engineering Vol. 2(2009), p. 332-335, in Chinese
[23] Chaokun Yang: Journal of Materials Engineering Vol. 7(2002), p. 33-39, in Chinese.
Online since: March 2011
Authors: Wen Fang Li, Xiang Yu Luo, Xue Li Jin
Effect of Aggregate Size and Gradation on the Ceramsite Sound-absorbing Materials
LUO Xiangyu 1,2,a LI Wenfang1,b JIN Xueli3,c
1College of Materials Science and Engineering, South China University of Technology, Guangzhou 510640, China;
2Guangzhou Building Materials Institute Co., Ltd.
Journal of Jiamusi University (Natural Science Edition), 2008, 5(26): 680-682 [5] GUO Wenjie, WAN Jinquan, MA Yiwen, WANG Yan.
Journal of South China University of Technology (Natural Science Edition), 2009, 12(37): 70-74 [6] YE Jiandong,, LUO Fangcong.
Journal of South China University of Technology (Natural Science Edition), 2010, 4(38): 71-75 [7] Iwase, T.
ACI Materials Journal, 2004,101(1): 82-91 [15] Neithalath, N.
Journal of Jiamusi University (Natural Science Edition), 2008, 5(26): 680-682 [5] GUO Wenjie, WAN Jinquan, MA Yiwen, WANG Yan.
Journal of South China University of Technology (Natural Science Edition), 2009, 12(37): 70-74 [6] YE Jiandong,, LUO Fangcong.
Journal of South China University of Technology (Natural Science Edition), 2010, 4(38): 71-75 [7] Iwase, T.
ACI Materials Journal, 2004,101(1): 82-91 [15] Neithalath, N.