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Online since: July 2024
Authors: Jing An, Wen Fang Xing, Hai Yun Zhang, Dan Yong Wang, Shu Hu Li, Hua Zhen Wei
This article establishes a molecular scale model of PBO microfibers, which can deeply understand the phenomenon and characteristics of damage to PBO fiber materials through molecular dynamics optimization.
It also theoretically predicts the structure and physical properties of such materials, reveals their failure mechanisms, and provides technical support for the research and development of military materials. 1.
The PBO small molecule chain model in Fig. 1 was established using the Material Studio 2019.
The fracture strength is about 33 GPa and the elongation is 14.5%, making it a typical "strong and tough" material.
References [1] Fan Xinnian, 2013 Synthetic Fiber Industry 36 12 [2] Tang Jiuying, 2007 China Personal Protective Equipment 1 23 [3] Wu Yonghua, 2003 Journal of Southeast University 33 468 [4] Yang Xiaozhen, 2002 Beijing: Science Press [5] Yang Lin, 2012 Harbin Institute of Technology [6] Yang Yong, Li Xianfeng and Yang Xiaozhen, 1997 Journal of Polymer Science 4 457 [7] Luo Jun, Tan Sheng and Zhou Enle, 1998 Journal of Higher Education Chemistry 19 2034 [8] Zhu Shenmin, Sun Hui and Cheng Shiyuan, 2001 Polymer Materials Science and Engineering 17 109 [9] TOORU KITAGAWA, 1998 Journal of Polymer Science: Part B: Polymer Physics 36 39 [10] Li Xia, 2006 Doctoral Dissertation
It also theoretically predicts the structure and physical properties of such materials, reveals their failure mechanisms, and provides technical support for the research and development of military materials. 1.
The PBO small molecule chain model in Fig. 1 was established using the Material Studio 2019.
The fracture strength is about 33 GPa and the elongation is 14.5%, making it a typical "strong and tough" material.
References [1] Fan Xinnian, 2013 Synthetic Fiber Industry 36 12 [2] Tang Jiuying, 2007 China Personal Protective Equipment 1 23 [3] Wu Yonghua, 2003 Journal of Southeast University 33 468 [4] Yang Xiaozhen, 2002 Beijing: Science Press [5] Yang Lin, 2012 Harbin Institute of Technology [6] Yang Yong, Li Xianfeng and Yang Xiaozhen, 1997 Journal of Polymer Science 4 457 [7] Luo Jun, Tan Sheng and Zhou Enle, 1998 Journal of Higher Education Chemistry 19 2034 [8] Zhu Shenmin, Sun Hui and Cheng Shiyuan, 2001 Polymer Materials Science and Engineering 17 109 [9] TOORU KITAGAWA, 1998 Journal of Polymer Science: Part B: Polymer Physics 36 39 [10] Li Xia, 2006 Doctoral Dissertation
Online since: June 2010
Authors: Lucjan Pająk, Józef Lelątko, G. Badura, P. Kwapuliński, Z. Stokłosa, Józef Rasek, G. Haneczok
Badura
1
, J.Rasek1 , Z.Stokłosa
1
,
G.Haneczok1
1
Institute of Materials Science, University of Silesia, Bankowa 12, 40-007 Katowice, Poland
pkwapuli@us.edu.pl
Keywords: soft magnetic materials, crystallization, magnetic properties, mechanical properties
Abstract.
Such a figure represents variation of material brittleness with a change of material microstructure.
Pająk, Journal of Alloys and Compounds 436 (2007) 43 [3] G.
Hono, Journal of Non-Crystalline Solids 354 (2008) 882 [5] S.
Tyrlik-Held, Archives of Materials Science and Engineering 29 (2008) 73 [6] H.
Such a figure represents variation of material brittleness with a change of material microstructure.
Pająk, Journal of Alloys and Compounds 436 (2007) 43 [3] G.
Hono, Journal of Non-Crystalline Solids 354 (2008) 882 [5] S.
Tyrlik-Held, Archives of Materials Science and Engineering 29 (2008) 73 [6] H.
Online since: October 2024
Authors: Silviana Silviana, Reynold Valentino Silvester, Dwi Maulana Rochman, Monica Evelina Gandasasmita, Intan Kristianingsih, Muhammad Syaichur Rohman
Material and Method
This research referenced articles from leading international journals, including Science Direct, SpringerLink, JSTOR, and the Scopus database.
Materials China, pp. 2280–2291, Nov. 01, 2018. doi: 10.1016/j.cjche.2018.08.020
Lu, ‘Designed porous carbon materials for efficient CO2 adsorption and separation’, Xinxing Tan Cailiao/New Carbon Materials, vol. 30, no. 6, pp. 481–501, Dec. 2015, doi: 10.1016/S1872-5805(15)60203-7
Mulyanti, ‘Synthesis of silica particles from rice straw waste using a simple extraction method’, in IOP Conference Series: Materials Science and Engineering, Institute of Physics Publishing, May 2016. doi: 10.1088/1757-899X/128/1/012040
Biesheuvel, ‘Review on the science and technology of water desalination by capacitive deionization’, Progress in Materials Science, vol. 58, no. 8.
Materials China, pp. 2280–2291, Nov. 01, 2018. doi: 10.1016/j.cjche.2018.08.020
Lu, ‘Designed porous carbon materials for efficient CO2 adsorption and separation’, Xinxing Tan Cailiao/New Carbon Materials, vol. 30, no. 6, pp. 481–501, Dec. 2015, doi: 10.1016/S1872-5805(15)60203-7
Mulyanti, ‘Synthesis of silica particles from rice straw waste using a simple extraction method’, in IOP Conference Series: Materials Science and Engineering, Institute of Physics Publishing, May 2016. doi: 10.1088/1757-899X/128/1/012040
Biesheuvel, ‘Review on the science and technology of water desalination by capacitive deionization’, Progress in Materials Science, vol. 58, no. 8.
Online since: February 2020
Authors: Rabab A. Shanab, Mohamed A. Attia, Salwa A. Mohamed, Norhan Alaa Mohamed
Functionally graded composite materials: an overview.
Procedia Materials Science, 5, 1291-1299
Paper presented at the Materials science forum
International Journal of Engineering Science, 64, 37-53
International Journal of Mechanics and Materials in Design, 13(3), 385-406
Procedia Materials Science, 5, 1291-1299
Paper presented at the Materials science forum
International Journal of Engineering Science, 64, 37-53
International Journal of Mechanics and Materials in Design, 13(3), 385-406
Online since: January 2015
Authors: Valeria Grebneva, Ksenia Utkina, Mohanad Sabri, Oleg Stolyarov
Accelerated creep testing for aramid fibres using the stepped isothermal method (2008) Journal of Materials Science, 43(14), pp. 4789-4800
Accelerated and real-time creep and creep-rupture results for aramid fibers (2012) Journal of Applied Polymer Science, 125(5), pp. 3856-3870
Prediction of the long-term behaviour of high modulus fibres using the stepped isostress method (SSM) (2011) Journal of Materials Science, 46(24), pp. 7660-7671
Comparison of accelerated compressive creep behavior of virgin HDPE using thermal and energy approaches (2011) Journal of Materials Engineering and Performance, 20(7), pp. 1219-1229
Predicting compressive creep behavior of virgin HDPE using thermal acceleration (2011) Journal of Materials in Civil Engineering, 23(8), pp. 1154-1162
Accelerated and real-time creep and creep-rupture results for aramid fibers (2012) Journal of Applied Polymer Science, 125(5), pp. 3856-3870
Prediction of the long-term behaviour of high modulus fibres using the stepped isostress method (SSM) (2011) Journal of Materials Science, 46(24), pp. 7660-7671
Comparison of accelerated compressive creep behavior of virgin HDPE using thermal and energy approaches (2011) Journal of Materials Engineering and Performance, 20(7), pp. 1219-1229
Predicting compressive creep behavior of virgin HDPE using thermal acceleration (2011) Journal of Materials in Civil Engineering, 23(8), pp. 1154-1162
Online since: May 2022
Authors: Wen Tao Wang, Zhi Zhang, Jing Wu, Chao Feng Yang
Journal of Mechanical Science and Technology, 2011, 25(5): 1159-65
Materials Science and Engineering: A, 2008, (483-484): 376-81
Journal of Materials Science, 2006, 41(22): 7324-32
Construction and Building Materials, 2017, (141): 52-32
A New Multiparameter Model for Multiaxial Fatigue Life Prediction of Rubber Materials.
Materials Science and Engineering: A, 2008, (483-484): 376-81
Journal of Materials Science, 2006, 41(22): 7324-32
Construction and Building Materials, 2017, (141): 52-32
A New Multiparameter Model for Multiaxial Fatigue Life Prediction of Rubber Materials.
Online since: November 2011
Authors: Marisa Masumi Beppu, Raquel Farias Weska, Mariana Agostini de Moraes, Mariana Ferreira Silva
Zhu: Journal of Materials Science-Materials in Medicine Vol. 15 (2004), p. 1193-1197
Freddi: Journal of Applied Polymer Science Vol. 104 (2007), p. 2187-2196
Wu: Journal of Applied Polymer Science Vol. 106 (2007), p. 53-59
Beppu: Materials Science & Engineering C-Materials for Biological Applications Vol. 30 (2010), p. 575-582
Kaplan: Journal of Materials Science Vol. 43 (2008), p. 6967-6985.
Freddi: Journal of Applied Polymer Science Vol. 104 (2007), p. 2187-2196
Wu: Journal of Applied Polymer Science Vol. 106 (2007), p. 53-59
Beppu: Materials Science & Engineering C-Materials for Biological Applications Vol. 30 (2010), p. 575-582
Kaplan: Journal of Materials Science Vol. 43 (2008), p. 6967-6985.
Online since: March 2021
Authors: Satoshi Namigata, Hideaki Tsukamoto
In this study, CNT/ aluminum (Al) matrix functionally graded materials (FGMs) have been focused on.
Due to these interesting properties, CNT can play a significant role in the fields of nanotechnology, electronics, optics and materials science.
Functionally graded materials (FGMs) are practically ideal concepts to protect the materials and structures working under super high temperatures and temperature gradients.
Centrifugal force direction Materials Characterization.
Tsukamoto, Microstructure and indentation properties of ZrO2/ Ti functionally graded materials fabricated by spark plasma sintering, Materials Science & Engineering A640: 338-349 (2015)
Due to these interesting properties, CNT can play a significant role in the fields of nanotechnology, electronics, optics and materials science.
Functionally graded materials (FGMs) are practically ideal concepts to protect the materials and structures working under super high temperatures and temperature gradients.
Centrifugal force direction Materials Characterization.
Tsukamoto, Microstructure and indentation properties of ZrO2/ Ti functionally graded materials fabricated by spark plasma sintering, Materials Science & Engineering A640: 338-349 (2015)
Online since: June 2015
Authors: R. Vignesh, A. Sabarish, K. Rajeshkannan, V. Nisanth, R. Arunkumar, K. Palanikumar, Ashwin Sailesh
Abstract- The developments in the field of composite materials are phenomenal.
Materials Used In the current investigation Banana fiber, Bamboo fiber, E-Glass fibers are used as reinforcement material and Epoxy resin (LY556) with a suitable hardener (HY951) is used as matrix material.
Method of Fabrication The composite materials were fabricated by using Hand – Layup technique.
[2] Hari Shankar.P, Ragavendra Rao.H, Chemical resistance and tensile properties of bamboo and glass fibers reinforced epoxy hybrid composites, International Journal in Advances in Polymer Science and Technology, Vol.2, No.3, pp. 27-29, 2011
[4] Raghavendra.S, Lingaraju, Balachandra Shetty.P, Mukunda.P.G, Mechanical Properties of Short Banana Fiber Reinforced Natural Rubber Composites, International Journal of Innovative Research in Science, Engineering and Technology, Vol.2, No.5, pp. 1652-1655, 2013
Materials Used In the current investigation Banana fiber, Bamboo fiber, E-Glass fibers are used as reinforcement material and Epoxy resin (LY556) with a suitable hardener (HY951) is used as matrix material.
Method of Fabrication The composite materials were fabricated by using Hand – Layup technique.
[2] Hari Shankar.P, Ragavendra Rao.H, Chemical resistance and tensile properties of bamboo and glass fibers reinforced epoxy hybrid composites, International Journal in Advances in Polymer Science and Technology, Vol.2, No.3, pp. 27-29, 2011
[4] Raghavendra.S, Lingaraju, Balachandra Shetty.P, Mukunda.P.G, Mechanical Properties of Short Banana Fiber Reinforced Natural Rubber Composites, International Journal of Innovative Research in Science, Engineering and Technology, Vol.2, No.5, pp. 1652-1655, 2013
Online since: August 2011
Authors: Wan Lin Guo, Liang He
It’s a multi-attribute decision problem to select optimized materials from different kinds of materials[3].
Journal of Cleaner Production,2008,16 (17):1887-1899
Material Science and Technology, 1989,5(6):517–525
Journal of Manufacturing Systems, 1996, 15 (1):1–12
Mater Science and Engineering A, 2006, 431 (1-2):248–255
Journal of Cleaner Production,2008,16 (17):1887-1899
Material Science and Technology, 1989,5(6):517–525
Journal of Manufacturing Systems, 1996, 15 (1):1–12
Mater Science and Engineering A, 2006, 431 (1-2):248–255