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Online since: August 2015
Authors: Sergey Veselov, Nina Cherkasova, Natalya Belousova, Ruslan Kuzmin, Aleksey Lazarev, Maksim Perepyolkin
Materials. 7 (2014) 5012-5037
Journal of Metals, Materials and Minerals. 20/2 (2010) 71-78
Applied Mechanics and Materials. 698 (2015) 457-460
Applied Mechanics and Materials. 698 (2015) 472-477
Applied Mechanics and Materials. 698 (2015) 513-518.
Journal of Metals, Materials and Minerals. 20/2 (2010) 71-78
Applied Mechanics and Materials. 698 (2015) 457-460
Applied Mechanics and Materials. 698 (2015) 472-477
Applied Mechanics and Materials. 698 (2015) 513-518.
Online since: September 2024
Authors: Farhan Aryo Hutomo, Azzah Dyah Pramata, Paundra Rizky Pratama
However, because of their low stability under humid conditions, Cu2O QDs must be combined with other materials to avert spontaneous transformation into CuO.
Materials and Method Materials.
Advanced Materials, 31(50), 1901997. (2019) [11] Hashimoto, K., Irie, H, A.
J., Gilbert-Bass, K., Chemistry of Materials, 31(7), 2677-2682. (2019) [15] Koiki, B.A. and Arotiba, O.A., RSC advances, 10(60), 36514-36525. (2020) [16] Yuan, B., Qian, H., Cao, L., Advanced Engineering Materials. (2023) [17] Sun, W., Guo, R., Shi, C., Catalysis Letters, 1-13. (2023) [18] Rej, S., Bisetto, M., Naldoni, A., Journal of Materials Chemistry A, 9(10), 5915-5951. (2021) [19] Giannozzi, P., Baseggio, O., The Journal of chemical physics, 152(15), 154105. (2020) [20] Giannozzi, P., Andreussi, O., Journal of physics: Condensed matter, 29(46), 465901. (2017) [21] Su, Y., Li, H., Ma, H., ACS Applied Materials & Interfaces, 9(9), 8100-8106. (2017) [22] Tsolekile, N., Ncapayi, V., International Journal of Nanomedicine, 7065-7078. (2019) [23] Muiruri, A., Maringa, M. and du Preez, W., Materials, 13(23), 5355. (2020) [24] Pattadar, D.K. and Zamborini, F.P., Langmuir, 35(50), 16416-16426. (2019) [25] Zheng, M.W., Yang, S.J., Pu, Y.C., Chemosphere, 307, 135984. (2022) [26] Chaves
, A., Azadani, J.G., Alsalman, H., npj 2D Materials and Applications, 4(1), 29. (2020) [27] Borlido, P., Aull, T., Journal of chemical theory and computation, 15(9), 5069-5079. (2019) [28] Jubu, P.R., Yam, F.K., Journal of Solid State Chemistry, 290, 121576. (2020) [29] Wu, K., Cao, M., Zeng, Q. and Li, X., Green Energy & Environment. (2022) [30] Mazarji, M., Kuthiala, S., Tsapekos, Science of the Total Environment, 682, 47-58. (2019) [31] Dervishi, E., Ji, Z., Htoon, H., Nanoscale, 11(35),16571-16581. (2019) [32] Guo, H., Zhang, R., Li, H., Nano Letters, 20(4), 2674-2680. (2020) [33] Yu, T., Zhao, Z., Journal of the American Chemical Society,141(4),1599-1605. (2019) [34] Abdolkarimi-Mahabadi, Theoretical and Experimental Chemistry, 57, 191-198. (2021) [35] Toe, C.Y., Scott, J., Amal, R. and Ng, Y.H.
Materials and Method Materials.
Advanced Materials, 31(50), 1901997. (2019) [11] Hashimoto, K., Irie, H, A.
J., Gilbert-Bass, K., Chemistry of Materials, 31(7), 2677-2682. (2019) [15] Koiki, B.A. and Arotiba, O.A., RSC advances, 10(60), 36514-36525. (2020) [16] Yuan, B., Qian, H., Cao, L., Advanced Engineering Materials. (2023) [17] Sun, W., Guo, R., Shi, C., Catalysis Letters, 1-13. (2023) [18] Rej, S., Bisetto, M., Naldoni, A., Journal of Materials Chemistry A, 9(10), 5915-5951. (2021) [19] Giannozzi, P., Baseggio, O., The Journal of chemical physics, 152(15), 154105. (2020) [20] Giannozzi, P., Andreussi, O., Journal of physics: Condensed matter, 29(46), 465901. (2017) [21] Su, Y., Li, H., Ma, H., ACS Applied Materials & Interfaces, 9(9), 8100-8106. (2017) [22] Tsolekile, N., Ncapayi, V., International Journal of Nanomedicine, 7065-7078. (2019) [23] Muiruri, A., Maringa, M. and du Preez, W., Materials, 13(23), 5355. (2020) [24] Pattadar, D.K. and Zamborini, F.P., Langmuir, 35(50), 16416-16426. (2019) [25] Zheng, M.W., Yang, S.J., Pu, Y.C., Chemosphere, 307, 135984. (2022) [26] Chaves
, A., Azadani, J.G., Alsalman, H., npj 2D Materials and Applications, 4(1), 29. (2020) [27] Borlido, P., Aull, T., Journal of chemical theory and computation, 15(9), 5069-5079. (2019) [28] Jubu, P.R., Yam, F.K., Journal of Solid State Chemistry, 290, 121576. (2020) [29] Wu, K., Cao, M., Zeng, Q. and Li, X., Green Energy & Environment. (2022) [30] Mazarji, M., Kuthiala, S., Tsapekos, Science of the Total Environment, 682, 47-58. (2019) [31] Dervishi, E., Ji, Z., Htoon, H., Nanoscale, 11(35),16571-16581. (2019) [32] Guo, H., Zhang, R., Li, H., Nano Letters, 20(4), 2674-2680. (2020) [33] Yu, T., Zhao, Z., Journal of the American Chemical Society,141(4),1599-1605. (2019) [34] Abdolkarimi-Mahabadi, Theoretical and Experimental Chemistry, 57, 191-198. (2021) [35] Toe, C.Y., Scott, J., Amal, R. and Ng, Y.H.
Online since: February 2011
Authors: Mariam Al-Ma'adeed, Alma Hodzic, Gozde Ozerkan, Saravanan Rajendran, Ramazan Kahraman
The environmental impact of these composite materials is compared to the impact of virgin PP and PE.
The input materials (proportions) of these compounds are described in Table 1.
Garraín, International Journal of Life Cycle Assessment, Vol. 14 (2009), p. 73-82 [2] P.
Verpoest: 14th European Conference on Composite Materials, Budapest, Hungary (2010) [5] P.
Elías, Journal of Science in Food and Agriculture, Vol. 86 (2007a), p. 1781-1789
The input materials (proportions) of these compounds are described in Table 1.
Garraín, International Journal of Life Cycle Assessment, Vol. 14 (2009), p. 73-82 [2] P.
Verpoest: 14th European Conference on Composite Materials, Budapest, Hungary (2010) [5] P.
Elías, Journal of Science in Food and Agriculture, Vol. 86 (2007a), p. 1781-1789
Online since: July 2011
Authors: Xing Wen Zhu, Wen Zhong Jiang, Xiao Zhou, Tie Zhu Xu, Li Zhe Li, Min Gong
The PTCR Performance of Nb-doped BaTiO3-NBT Ceramics
Li Lizhe, Zhu Xingwena, Xu Tiezhu, Gong Min, Jiang Wenzhong, Zhou Xiao
School of Materials Science and Technology, Shanghai University, Shanghai(200072), China
axingwenzhu@shu.edu.cn
Keywords: lead-free PTCR; BBNT; high Curie temperature; Nb-doped
Abstract.
For comparison, undoped BBNT materials were also presented.
Nb2O5 dopant can considerably decrease the room-temperature resistance of BBNT materials.
L5 (2010), p.498 [3] Wang D Y, Li K, Chan H L W: Applied Physics A: Materials Science and Processing Vol. 80( 2005), p. 1531 [4] Gomah-Pettry, Jean-Richard, Said, Senda, Marchet, Pascal and Mercurio Jean-Pierre: Journal of the European Ceramic Society Vol. 24(2004), p 1165 [5] Hiroaki Takeda, Wataru Aoto and Tadashi Shiosaki: Applied Physics LettersVol.87(2005), p.102 [6] Ping-Hua X, H.
Shiosaki: Journal of the European Ceramic SocietyVol.27(2007), p.3877
For comparison, undoped BBNT materials were also presented.
Nb2O5 dopant can considerably decrease the room-temperature resistance of BBNT materials.
L5 (2010), p.498 [3] Wang D Y, Li K, Chan H L W: Applied Physics A: Materials Science and Processing Vol. 80( 2005), p. 1531 [4] Gomah-Pettry, Jean-Richard, Said, Senda, Marchet, Pascal and Mercurio Jean-Pierre: Journal of the European Ceramic Society Vol. 24(2004), p 1165 [5] Hiroaki Takeda, Wataru Aoto and Tadashi Shiosaki: Applied Physics LettersVol.87(2005), p.102 [6] Ping-Hua X, H.
Shiosaki: Journal of the European Ceramic SocietyVol.27(2007), p.3877
Online since: July 2014
Authors: D. Loganathan, A. Gnanavelbabu
Forming shapes mainly depend on the physical and mechanical properties of materials.
Soaking improves the grain structure of materials yields better formability [5, 6].
[4] D.Maisonnette, M.Suery, D.Nelias, P.Chaudet and T.Epicier, Effects of heat treatments on the microstructure and mechanical properties of a 6061 aluminium alloy, Materials Science and Engineering, A 528 (2011), pp.2718–2724
[9] D Li and Amit Gosh, Tensile Behaviour of Aluminium alloys at Warm forming temperatures, Materials Science and Engineering, (2002), pp.279 – 286
[10] Jun Liu and Ming-Jen Tan, Formability of AA5083 and AA6061 alloys for light weight applications, Journal of Materials Design, (2009), pp.S66 – S70.
Soaking improves the grain structure of materials yields better formability [5, 6].
[4] D.Maisonnette, M.Suery, D.Nelias, P.Chaudet and T.Epicier, Effects of heat treatments on the microstructure and mechanical properties of a 6061 aluminium alloy, Materials Science and Engineering, A 528 (2011), pp.2718–2724
[9] D Li and Amit Gosh, Tensile Behaviour of Aluminium alloys at Warm forming temperatures, Materials Science and Engineering, (2002), pp.279 – 286
[10] Jun Liu and Ming-Jen Tan, Formability of AA5083 and AA6061 alloys for light weight applications, Journal of Materials Design, (2009), pp.S66 – S70.
Online since: February 2014
Authors: Yan Hua Cai
Study on Effect of Rice Flour on Isothermal Crystallization Kinetics of Biodegradable Poly(L-lactic acid)
Cai Yan-Hua1
1School of Materials and Chemical Engineering, Chongqing University of Arts and Sciences, Yongchuan, Chongqing-402160, P.R.
Introduction Poly(L-lactic acid)(PLLA) is one of the most promising bio-based materials both science research and technology development field, and has been gaining more and more interest in recent years[1-2].
PLLA and MF are green materials, thus, it is very necessary to blend PLLA and MF to control the considerable environmental problems, what is more, the blend of PLLA and MF may develop more multi-functional biodegradable polymer composites.
Experimental Section 2.1 Materials PLLA (Mw=1.95×105) was purchased from Nature Works LLC, USA.
Sinha Ray, J Therm Anal Calorim, 113(2013), 703 [7] Jian-Feng Zhang and Xiuzhi Sun, Journal of Applied Polymer Science, 94(2004), 1697 [8] Tsutomu Ohkita and Seung-Hwan Lee, Journal of Applied Polymer Science, 100(2006), 3009 [9] Jie Cai, Miao Liu, Li Wang, Kunhua Yao, Sha Li and Hanguo Xiong, Carbohydrate Polymers, 86(2011), 941 [10] Li Chen, Xueyu Qiu, Mingxiao Deng, Zhongkui Hong, Rui Luo, Xuesi Chen and Xiabin Jing, Polymer, 46(2005), 5723
Introduction Poly(L-lactic acid)(PLLA) is one of the most promising bio-based materials both science research and technology development field, and has been gaining more and more interest in recent years[1-2].
PLLA and MF are green materials, thus, it is very necessary to blend PLLA and MF to control the considerable environmental problems, what is more, the blend of PLLA and MF may develop more multi-functional biodegradable polymer composites.
Experimental Section 2.1 Materials PLLA (Mw=1.95×105) was purchased from Nature Works LLC, USA.
Sinha Ray, J Therm Anal Calorim, 113(2013), 703 [7] Jian-Feng Zhang and Xiuzhi Sun, Journal of Applied Polymer Science, 94(2004), 1697 [8] Tsutomu Ohkita and Seung-Hwan Lee, Journal of Applied Polymer Science, 100(2006), 3009 [9] Jie Cai, Miao Liu, Li Wang, Kunhua Yao, Sha Li and Hanguo Xiong, Carbohydrate Polymers, 86(2011), 941 [10] Li Chen, Xueyu Qiu, Mingxiao Deng, Zhongkui Hong, Rui Luo, Xuesi Chen and Xiabin Jing, Polymer, 46(2005), 5723
Online since: June 2008
Authors: Mircea Chipara, William J. Brittain, Magdalena Dorina Chipara, Kin Tak Lau
Materials Science &
Engineering R-Reports, 43, 61-102
Chemistry of Materials, 17, 130-135
Journal of Optoelectronics and Advanced Materials, 6, 817-824
Journal of Optoelectronics and Advanced Materials, 6, 297-305
Science and Engineering of Composite Materials, 11, 19-26
Chemistry of Materials, 17, 130-135
Journal of Optoelectronics and Advanced Materials, 6, 817-824
Journal of Optoelectronics and Advanced Materials, 6, 297-305
Science and Engineering of Composite Materials, 11, 19-26
Online since: October 2018
Authors: G.V. Pachurin, S.M. Shevchenko, M.V. Mukhina
Along with design factors, reliability of the work-pieces for machines and mechanisms is a function of the structure and the properties of the implied materials; these properties depend significantly on the kind and the mode of the process treatment.
Introduction Along with design factors [1-4], reliability of machine and mechanism work-pieces is a function of the structure and the properties of the implied materials; these properties depend significantly on the kind and the mode of the process treatment [5-7].
Pachurin, Ruggedness of Structural Material and Service Life of Metal Components (Vol. 38) Steel in Translation, 3 (2008) 217-220
International Journal of Applied and Fundamental Research, 2, part 2 (2014) 28-33
Pachurin, Interrelation Between Structural & Mechanical Properties and Fatigue Resistance of Hot Deformed Material.
Introduction Along with design factors [1-4], reliability of machine and mechanism work-pieces is a function of the structure and the properties of the implied materials; these properties depend significantly on the kind and the mode of the process treatment [5-7].
Pachurin, Ruggedness of Structural Material and Service Life of Metal Components (Vol. 38) Steel in Translation, 3 (2008) 217-220
International Journal of Applied and Fundamental Research, 2, part 2 (2014) 28-33
Pachurin, Interrelation Between Structural & Mechanical Properties and Fatigue Resistance of Hot Deformed Material.
Online since: January 2021
Authors: Hong Yang Li, Song Yu, Hai Ping Deng
[4] Godwin, John, Hydroforming Starts to Make an Impression, Materials World , Insts of Materials, 1998,6(8): 483-484
,The Tube Bending Technology of a Hydroforming Process for an Automotive Part, Journal of Materials Processing Technology, 2001,111(3),:175-181
Zhang, Developments in hydroforming[J], Journal of Materials Processing Technology 91 (1999) 236–244
Materials Science & Engineering A, 2013, Vol.569: 137-143
Journal of Computer-Aided Materials Design, 2002, 9(2): 145-163
,The Tube Bending Technology of a Hydroforming Process for an Automotive Part, Journal of Materials Processing Technology, 2001,111(3),:175-181
Zhang, Developments in hydroforming[J], Journal of Materials Processing Technology 91 (1999) 236–244
Materials Science & Engineering A, 2013, Vol.569: 137-143
Journal of Computer-Aided Materials Design, 2002, 9(2): 145-163
Online since: August 2014
Authors: Rashid Ahmed, Ul Haq Bakhtiar, A. Shaari, Muhammad Zaki bin Yaacob
Solar energy materials and solar cells, 2002. 73(1): p. 51-58
Advanced Materials for Optics and Electronics, 1999. 9(5): p. 205-209
Solid State Sciences, 2012. 14(6): p. 698-704
Solid State Sciences, 2011. 13(2): p. 384-387
Materials Science in Semiconductor Processing, 2013
Advanced Materials for Optics and Electronics, 1999. 9(5): p. 205-209
Solid State Sciences, 2012. 14(6): p. 698-704
Solid State Sciences, 2011. 13(2): p. 384-387
Materials Science in Semiconductor Processing, 2013