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Online since: November 2022
Authors: Kannachai Kanlayasiri, Niwat Mookam, Prajak Jattakul
Materials Science and Engineering R. 2000; 27: 95-141
Journal of Materials Science: Materials in Electronics. 2011; 22: 565-578
Journal of Materials Research. 2010; 25: 303-314
Journal of Electronic Materials. 2001; 30: 45-52
Journal of Materials Science. 2003; 38(6): 1269-1279
Journal of Materials Science: Materials in Electronics. 2011; 22: 565-578
Journal of Materials Research. 2010; 25: 303-314
Journal of Electronic Materials. 2001; 30: 45-52
Journal of Materials Science. 2003; 38(6): 1269-1279
Online since: August 2014
Authors: Sylvain Fréour, Viwanou Hounkpati, David Gloaguen, Vincent Legrand
Guillén, Materials Science Forum, 681 (2011), 97-102
Jacquemin, Mechanics of Materials, 42 (2010), 218-226
Weng, Mechanics of Materials, 12 (1991), 1-15
Li, Mechanics of Materials, 31 (1999), 149-159
Bunge, Texture analysis in materials science, Butterworth's edition, London, 1982
Jacquemin, Mechanics of Materials, 42 (2010), 218-226
Weng, Mechanics of Materials, 12 (1991), 1-15
Li, Mechanics of Materials, 31 (1999), 149-159
Bunge, Texture analysis in materials science, Butterworth's edition, London, 1982
Online since: January 2012
Authors: Wen Bai Liu, Chao Shen, Xia Li, Hong Ming Jiang
Experiment
Experimental facilities and sample material
Raw material is common Portland cement of which grade is P.S42.5.
Whole-field deformation measurement of concrete structure based on digital image correlation(In Chinese).Journal of southeast university(Natural science edition). 2010,40(4)
Journal of hefei university of technology(Natural science). 2009,32(12),1904—1909
Journal of hohai university(Natural science).2007(01)
Chinese journal of geotechnical engineering.2011,30(1)
Whole-field deformation measurement of concrete structure based on digital image correlation(In Chinese).Journal of southeast university(Natural science edition). 2010,40(4)
Journal of hefei university of technology(Natural science). 2009,32(12),1904—1909
Journal of hohai university(Natural science).2007(01)
Chinese journal of geotechnical engineering.2011,30(1)
Online since: August 2014
Authors: Ping Zhong, Lin Xiu Cheng
It follows that the hydrochloric acid doped polyaniline is the main material embodied catalytic properties.
Acknowledgements This work was financially supported by National Science Foundation of Jiangxi province (20122BAB213012).
Chen, The preparation of Acid doped nanostructured polyaniline fiber and the study of the esterification performance, Journal of science and technology of kunming university (edition of science), 35(2)(2010)98-101
Yang, The application and research progress of polyaniline in catalytic field, Polymer Materials Science and Engineering, 26 (9) (2010) 159-162
Meng etc., Journal of shandong institute of building materials, 13 (3) (1999) 259-261
Acknowledgements This work was financially supported by National Science Foundation of Jiangxi province (20122BAB213012).
Chen, The preparation of Acid doped nanostructured polyaniline fiber and the study of the esterification performance, Journal of science and technology of kunming university (edition of science), 35(2)(2010)98-101
Yang, The application and research progress of polyaniline in catalytic field, Polymer Materials Science and Engineering, 26 (9) (2010) 159-162
Meng etc., Journal of shandong institute of building materials, 13 (3) (1999) 259-261
Online since: April 2021
Authors: Sergey N. Khimukhin, Kseniia P. Eremina
Cathode nickel and aluminum (A7) were used as charge materials.
Shilov, Studying the dynamics of the process of transferring electrode materials in a high-current pulsed discharge, Electronic processing of materials. 4 (1977) 18–19
Sheldon, Advances in the electrospark deposition coating process, Journal of Vacuum Science & Technology A: Vacuum, Surfaces, and Films. 4 (1986) 2740–2746
Brown, Electro-Spark Deposition, Advanced Materials and Processes. 161 (2003) 35–37
Brochu, Development of a nanostructure microstructure in the Al – Ni system using the electrospark deposition process, Journal of Materials Processing Technology. (2010) 892-898
Shilov, Studying the dynamics of the process of transferring electrode materials in a high-current pulsed discharge, Electronic processing of materials. 4 (1977) 18–19
Sheldon, Advances in the electrospark deposition coating process, Journal of Vacuum Science & Technology A: Vacuum, Surfaces, and Films. 4 (1986) 2740–2746
Brown, Electro-Spark Deposition, Advanced Materials and Processes. 161 (2003) 35–37
Brochu, Development of a nanostructure microstructure in the Al – Ni system using the electrospark deposition process, Journal of Materials Processing Technology. (2010) 892-898
Online since: September 2013
Authors: Mohd Arif Anuar Mohd Salleh, Kazuhiro Nogita, Stuart Mcdonald
Gupta, Journal of Materials Engineering and Performance2010, 19, 335-341
Kangooie, Materials Science & Engineering A2011, 528, 3967-3972
Kamat, Materials Science & Engineering A2011, 529, 257-264
Arifin, Materials Science & Engineering A2012, 1-5
Chen, Materials Science and Engineering A2012, 545, 194– 200.
Kangooie, Materials Science & Engineering A2011, 528, 3967-3972
Kamat, Materials Science & Engineering A2011, 529, 257-264
Arifin, Materials Science & Engineering A2012, 1-5
Chen, Materials Science and Engineering A2012, 545, 194– 200.
Online since: September 2017
Authors: Basil T. Wong, Japheth Z.J. Lau
(10)
Multiple emitter materials are included in this paper.
Drude model parameters for two types of ITO materials.
The three substrate materials are Ag, W and SiC.
Solar energy materials and solar cells, 2001. 66(1): p. 443-452
[4] West, P.R., et al., Searching for better plasmonic materials.
Drude model parameters for two types of ITO materials.
The three substrate materials are Ag, W and SiC.
Solar energy materials and solar cells, 2001. 66(1): p. 443-452
[4] West, P.R., et al., Searching for better plasmonic materials.
Online since: January 2012
Authors: Ying Wei Yun, Cun Liang Hu, Il Young Jang, Yan Wu Ji, Il Soo Kim, Hui Lin Li, Seong Kyum Kim, Bi Peng Xu
Journal of Korea concrete institute.
Journal of Korea concrete institute.
Journal of Korea concrete institute.
Journal of South-west University of Science and Technology.
International Journal of Concrete structures and material, Vol.2, No.1, (2008), p.63.
Journal of Korea concrete institute.
Journal of Korea concrete institute.
Journal of South-west University of Science and Technology.
International Journal of Concrete structures and material, Vol.2, No.1, (2008), p.63.
Online since: May 2016
Authors: J.L. Wang, W.W. Song
,Computational Materials Science. 2009, 44: 858-866
Murakawa, Computational Materials Science.2008, (43):591-607
Lee, Journal of Materials ProcessingThchnology.2008, 23: 305-353
John, Materials Science and Engineering A, 2008, (490): 427-437
Goldak, Computational Materials Science. 2009, 44, : 841-849
Murakawa, Computational Materials Science.2008, (43):591-607
Lee, Journal of Materials ProcessingThchnology.2008, 23: 305-353
John, Materials Science and Engineering A, 2008, (490): 427-437
Goldak, Computational Materials Science. 2009, 44, : 841-849
Online since: April 2021
Authors: Rong Liu, Peng Qing, Ge Jian Zhu
Among the synthetic polymer materials, PLGA is one of the most popular carrier materials in recent years.
Ischemic Stroke Treatment and PLGA Nanomaterials PLGA is currently considered to be one of the most promising biomedical polymer-degradable materials.
Biodegradable polymer nanoparticles (nanoparticles, NPs) materials are mainly divided into synthetic biodegradable polymers and natural macromolecular systems.
Acknowledgments We thank the support by Youth Science Fund Project of National Natural Science Foundation of China (No. 81704172).
Enhanced thrombolysis using tissue plasminogen activator (tPA)-loaded PEGylated PLGA nanoparticles for ischemic stroke, Journal of Drug Delivery Science and Technology. 53 (2019) 101
Ischemic Stroke Treatment and PLGA Nanomaterials PLGA is currently considered to be one of the most promising biomedical polymer-degradable materials.
Biodegradable polymer nanoparticles (nanoparticles, NPs) materials are mainly divided into synthetic biodegradable polymers and natural macromolecular systems.
Acknowledgments We thank the support by Youth Science Fund Project of National Natural Science Foundation of China (No. 81704172).
Enhanced thrombolysis using tissue plasminogen activator (tPA)-loaded PEGylated PLGA nanoparticles for ischemic stroke, Journal of Drug Delivery Science and Technology. 53 (2019) 101