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Online since: May 2021
Authors: Faizul Che Pa, Abdullah Chik, Yeoh Cheow Keat, Akeem Adekunle Adewale, Ruhiyuddin Mohd Zaki
The search for clean energy conversion technologies promotes the study of thermoelectric materials.
Developing a good TE materials require that these materials have high Seebeck coefficient, and lower electrical resistivity as well as lower total thermal conductivity.
Thus, oxides become promising since these materials are less toxic for TE devices.
Arif, Effect of al doping concentration to the physical and thermoelectric properties of zinc oxide, Australian Journal of Basic and Applied Sciences 7(5) (2013) 21-25
Persson, The Materials Project: A materials genome approach to accelerating materials innovation, APL Materials 1(1) (2013) 011002
Developing a good TE materials require that these materials have high Seebeck coefficient, and lower electrical resistivity as well as lower total thermal conductivity.
Thus, oxides become promising since these materials are less toxic for TE devices.
Arif, Effect of al doping concentration to the physical and thermoelectric properties of zinc oxide, Australian Journal of Basic and Applied Sciences 7(5) (2013) 21-25
Persson, The Materials Project: A materials genome approach to accelerating materials innovation, APL Materials 1(1) (2013) 011002
Online since: October 2023
Authors: Zhi Kai Zhou, Wu Yin Jin, Xia Zhang, Wen Ke Chen, Shou Rui Wang
Journal
of Materials Processing Technology 2020; 278: 116500
Materials 2019; 12: 177-196
Journal of Materials Processing Technology 2020; 278: 116494
Journal of Materials Engineering and Performance 2016; 25: 5076-5086
Journal of Materials Processing Technology 2017; 247: 111-120
Materials 2019; 12: 177-196
Journal of Materials Processing Technology 2020; 278: 116494
Journal of Materials Engineering and Performance 2016; 25: 5076-5086
Journal of Materials Processing Technology 2017; 247: 111-120
Online since: September 2010
Authors: Tibor Czigány, Mátyás Andó, Gábor Kalácska
Journal of Applied Polymer
Science Vol. 91 (2004) p. 3866-3870
[2] G.
Journal of Optoelectronics and Advanced Materials Vol. 9 (2007) p. 2102-2109 [3] H.Y.
Materials Science Vol. 41 (2005) p. 265-270 [8] J.H.
Materials Letters Vol. 60 (2005) p. 746-749 [9] P.
Journal of Applied Polymer Science Vol. 101. (2006) p. 1799-1805 [11] W.
Journal of Optoelectronics and Advanced Materials Vol. 9 (2007) p. 2102-2109 [3] H.Y.
Materials Science Vol. 41 (2005) p. 265-270 [8] J.H.
Materials Letters Vol. 60 (2005) p. 746-749 [9] P.
Journal of Applied Polymer Science Vol. 101. (2006) p. 1799-1805 [11] W.
Online since: December 2014
Authors: Jing Zhang, Yuan Tian, Yu Guang Wang, Guo Dong Liu
Journal of Materials Science, Vol. 28(1993), p 5456
Chandrasekaran, Journal of Electronic Materials, Vol. 35(2006), p 941
Sasaki, Journal of Materials Chemistry, Vol. 14(2004), p 248
Du, Journal of Materials Chemistry., Vol. 12(2002), p 98
B., et al.Journal of Materials Chemistry, Vol. 16(2006), p 2082
Chandrasekaran, Journal of Electronic Materials, Vol. 35(2006), p 941
Sasaki, Journal of Materials Chemistry, Vol. 14(2004), p 248
Du, Journal of Materials Chemistry., Vol. 12(2002), p 98
B., et al.Journal of Materials Chemistry, Vol. 16(2006), p 2082
Online since: February 2018
Authors: Jia Liang Luo, Chao Hao Hu, Jun Qing Chang, Yan Zhong, Zong Wei Ji, Yi Fan Li, Lian Sheng Zhong
Su: Materials Science in Semiconductor Progressing, Vol. 15 (2012), p. 20-26
[6] Z.G.
Li: Materials Science in Semiconductor Processing, Vol. 16 (2013), p. 62-69 [10] A.
Zhu: Journal of Materials Chemistry, Vol. 17 (2007), p. 2526-2532 [15] A.
Zhu: Computational Materials Science, Vol. 43 (2008), p. 1101-1108 [21] X.
Xu: Journal of Hazardous Materials, Vol. 196 (2011), p. 255-262 [30] T.
Li: Materials Science in Semiconductor Processing, Vol. 16 (2013), p. 62-69 [10] A.
Zhu: Journal of Materials Chemistry, Vol. 17 (2007), p. 2526-2532 [15] A.
Zhu: Computational Materials Science, Vol. 43 (2008), p. 1101-1108 [21] X.
Xu: Journal of Hazardous Materials, Vol. 196 (2011), p. 255-262 [30] T.
Online since: February 2014
Authors: Riana Tri Setyadhani, Anif Jamaludin, Yofentina Iriani
Another thing to be considered is the amount of valence electrons of the materials.
Indonesian Journal of Materials Science (2008) 205-208
The influence of Mg doping on the materials properties of Ba1-xSrxTiO3 thin films for tunable device applications.
Materials Letters (2000) 34-41
Indonesian Journal of Material Science ,Vol 9 (2008) 245-248.
Indonesian Journal of Materials Science (2008) 205-208
The influence of Mg doping on the materials properties of Ba1-xSrxTiO3 thin films for tunable device applications.
Materials Letters (2000) 34-41
Indonesian Journal of Material Science ,Vol 9 (2008) 245-248.
Online since: August 2007
Authors: Mrityunjay Singh, Michael C. Halbig
Bonding and Integration of Silicon Carbide Based Materials for
Multifunctional Applications
M.
The objective was to study the bonds between different materials and to identify the optimal bonding materials and processing conditions.
Pressure* Time Atmosphere Cooling Rate Analysis [˚C] [MPa] [hr] [˚C/min] A (materials 1, 2, and 3) 1250 24, 24, 31 2 vacuum 5 microsopy & microprobe B (materials 1 and 3) 1300 24, 31 2 vacuum 2 microscopy C (materials 1 and 3) 1250 50, 50 2 vacuum 2 microscopy D (materials 1, 4 and 5) 1250 24, 31, 31 2 vacuum 2 microscopy & microprobe * at the minimun clamping pressure (except for 50 MPa), the pressure listed is with respect to the correlating material combination Table 3.
Singh, "Interfacial and Thermal Characterization of Reaction Formed Joints in Silicon Carbide-Based Materials," J. of the Eur.
Schmid-Fetzer, "Solid-State Bonding of Silicon Carbide (HIP-SiC) Below 1000˚C," Materials Science and Engineering, A220, 35-40 (1996)
The objective was to study the bonds between different materials and to identify the optimal bonding materials and processing conditions.
Pressure* Time Atmosphere Cooling Rate Analysis [˚C] [MPa] [hr] [˚C/min] A (materials 1, 2, and 3) 1250 24, 24, 31 2 vacuum 5 microsopy & microprobe B (materials 1 and 3) 1300 24, 31 2 vacuum 2 microscopy C (materials 1 and 3) 1250 50, 50 2 vacuum 2 microscopy D (materials 1, 4 and 5) 1250 24, 31, 31 2 vacuum 2 microscopy & microprobe * at the minimun clamping pressure (except for 50 MPa), the pressure listed is with respect to the correlating material combination Table 3.
Singh, "Interfacial and Thermal Characterization of Reaction Formed Joints in Silicon Carbide-Based Materials," J. of the Eur.
Schmid-Fetzer, "Solid-State Bonding of Silicon Carbide (HIP-SiC) Below 1000˚C," Materials Science and Engineering, A220, 35-40 (1996)
Online since: November 2014
Authors: Dariusz Boroński, Zbigniew Lutowski, Robert Sołtysiak
Kaliskiego 7, 85-789 Bydgoszcz, POLAND
2 University of Technology and Life Sciences, Faculty of Telecommunication, Computer Science and Electrical Engineering, al. prof.
International Journal of Fatigue 18, (1996) 153-170
Boroński, Material Properties Investigations With the Use of Microspecimen, Materials Science Forum 726 (2012) 51-54
Boroński, Methods of strain and stress investigations in fatigue of materials and structures, Publishing House of ITeE-PIB, Bydgoszcz-Radom (2007) (in polish)
Key Engineering Materials Vol. 598 (2014), pp. 26-31.
International Journal of Fatigue 18, (1996) 153-170
Boroński, Material Properties Investigations With the Use of Microspecimen, Materials Science Forum 726 (2012) 51-54
Boroński, Methods of strain and stress investigations in fatigue of materials and structures, Publishing House of ITeE-PIB, Bydgoszcz-Radom (2007) (in polish)
Key Engineering Materials Vol. 598 (2014), pp. 26-31.
Online since: March 2019
Authors: Ahmad Kusumaatmaja, Iman Santoso, Fiqhri Heda Murdaka, Isnaeni Isnaeni
Wu, Electrophoretic fabrication of highly robust, efficient, and benign heterojunction photoelectrocatalysts based on graphene-quantum-dot sensitized TiO 2 nanotube arrays, Journal of Materials Chemistry A. 1.11 (2013) 3551-3555
Wu, Hydrothermal route for cutting graphene sheets into blue‐luminescent graphene quantum dots, Advanced materials. 22.6 (2010) 734-738
Qu, An electrochemical avenue to green‐luminescent graphene quantum dots as potential electron‐acceptors for photovoltaics, Advanced materials. 23.6 (2011) 776-780
Saxena, Optical properties of few layered graphene quantum dots, Materials Research Express. 2.9 (2015) 095024
Ruoff, Stable aqueous dispersions of graphitic nanoplatelets via the reduction of exfoliated graphite oxide in the presence of poly (sodium 4-styrenesulfonate), Journal of Materials Chemistry. 16.2 (2006) 155-158
Wu, Hydrothermal route for cutting graphene sheets into blue‐luminescent graphene quantum dots, Advanced materials. 22.6 (2010) 734-738
Qu, An electrochemical avenue to green‐luminescent graphene quantum dots as potential electron‐acceptors for photovoltaics, Advanced materials. 23.6 (2011) 776-780
Saxena, Optical properties of few layered graphene quantum dots, Materials Research Express. 2.9 (2015) 095024
Ruoff, Stable aqueous dispersions of graphitic nanoplatelets via the reduction of exfoliated graphite oxide in the presence of poly (sodium 4-styrenesulfonate), Journal of Materials Chemistry. 16.2 (2006) 155-158
Online since: November 2007
Authors: Terry C. Lowe
Benson, Progress in Materials Science, 2006. 51(4): p. 427-
556.
12.
Kim, Materials Science and Engineering A, 2002. 337(1-2): p. 39-44. 15.
Korznikova, Materials Science Forum, 2006. 503-504: p. 57-64. 20.
Hao, Journal of Computer-Aided Materials Design, 2004. 11(2-3): p. 139-161. 25.
Baskes, Journal of Materials Research, 1990. 5(2): p. 313-24. 31.
Kim, Materials Science and Engineering A, 2002. 337(1-2): p. 39-44. 15.
Korznikova, Materials Science Forum, 2006. 503-504: p. 57-64. 20.
Hao, Journal of Computer-Aided Materials Design, 2004. 11(2-3): p. 139-161. 25.
Baskes, Journal of Materials Research, 1990. 5(2): p. 313-24. 31.