Sort by:
Publication Type:
Open access:
Publication Date:
Periodicals:
Search results
Online since: May 2016
Authors: Roman Koleňák, Igor Kostolný, Daniel Dřímal, Andrej Rabatin
In Journal of Electronic Materials, Vol. 23, No. 8, 1994, pp. 701-707
[2] SHU, M.H., HSU, B.M., HU, M.C.
In Materials Science and Engineering B55, 1998, pp. 5-13
In Journal of Materials Science Letters, Vol. 19, Is. 14, 2000, pp. 1241-1242
In Materials Science and Engineering B25, 1994, pp. 39-46
In Materials Science and Engineering, roč. 44, č. 1, 1-44 s., 2004.
In Materials Science and Engineering B55, 1998, pp. 5-13
In Journal of Materials Science Letters, Vol. 19, Is. 14, 2000, pp. 1241-1242
In Materials Science and Engineering B25, 1994, pp. 39-46
In Materials Science and Engineering, roč. 44, č. 1, 1-44 s., 2004.
Online since: November 2014
Authors: Adam Lipski, Zbigniew Lis
Skibicki, Variations Of The Specimen Temperature Depending On The Pattern
Of The Multiaxial Load - Preliminary Research, Materials Science Forum, 726 (2012), 162-168
Boroński, Use of Thermography for the Analysis of Strength Properties of Mini-Specimens, Materials Science Forum, 726 (2012), 156-161
Risitano, Thermographic methodology for rapid determination of the fatigue limit of materials and mechanical components, International Journal of Fatigue, 22, 1 (2000), 65–73
Ait-Amokhtar et al., The dynamics of Portevin–Le Chatelier bands in an Al–Mg alloy from infrared thermography, Materials Science and Engineering: A, 488, 1-2 (2008), 540–546
Arrieux, Thermal observations associated with the Portevin–Le Châtelier effect in an Al–Mg alloy, Materials Science and Engineering: A, 404, 1-2 (2005), 188–196
Boroński, Use of Thermography for the Analysis of Strength Properties of Mini-Specimens, Materials Science Forum, 726 (2012), 156-161
Risitano, Thermographic methodology for rapid determination of the fatigue limit of materials and mechanical components, International Journal of Fatigue, 22, 1 (2000), 65–73
Ait-Amokhtar et al., The dynamics of Portevin–Le Chatelier bands in an Al–Mg alloy from infrared thermography, Materials Science and Engineering: A, 488, 1-2 (2008), 540–546
Arrieux, Thermal observations associated with the Portevin–Le Châtelier effect in an Al–Mg alloy, Materials Science and Engineering: A, 404, 1-2 (2005), 188–196
Online since: January 2013
Authors: Xin Qian, Yang Fu Jin, Fang Qin Yang
Simulation and Experiment
Model and materials parameters.
Materials Parameters and condition are shown in Table 1.
(2) Thermal conductivity of materials doesn’t change with temperature.
:Polymer Materials Science and Engineering, 2000, Vol. 16(4): p. 17-20.In Chinese
[2] X W Zhao,L Ye.: Journal of Applied polymer Science, 2009, Vol. 111(2): p. 759-767
Materials Parameters and condition are shown in Table 1.
(2) Thermal conductivity of materials doesn’t change with temperature.
:Polymer Materials Science and Engineering, 2000, Vol. 16(4): p. 17-20.In Chinese
[2] X W Zhao,L Ye.: Journal of Applied polymer Science, 2009, Vol. 111(2): p. 759-767
Online since: June 2019
Authors: Daniel Hülsbusch, Frank Walther, Patrick Striemann, Michael Niedermeier
Olmi, Experimental characterization and analytical modelling of the mechanical behavior of fused deposition processed parts made of ABS-M30, Computational Materials Science 79 (2013) 506-518
Holzer, Parametric optimization of intra- and inter-layer strengths in parts produced by extrusion-based additive manufacturing of poly(lactic acid), Journal of Applied Polymer Science 134 (2017) 1-15
Walther, Compression testing of additively manufactured continuous carbon fiber-reinforced sandwich structures, Materials Testing 60 (2018) 801-808
Renaud, Mechanical behavior of acrylonitrile butadiene styrene (ABS) fused deposition materials.
Experimental investigation, Rapid Prototyping Journal 7 (2001) 148-158.
Holzer, Parametric optimization of intra- and inter-layer strengths in parts produced by extrusion-based additive manufacturing of poly(lactic acid), Journal of Applied Polymer Science 134 (2017) 1-15
Walther, Compression testing of additively manufactured continuous carbon fiber-reinforced sandwich structures, Materials Testing 60 (2018) 801-808
Renaud, Mechanical behavior of acrylonitrile butadiene styrene (ABS) fused deposition materials.
Experimental investigation, Rapid Prototyping Journal 7 (2001) 148-158.
Online since: April 2014
Authors: Kornkamol Natrchalayuth, Pornapa Sujaridworakun
Photocatalytic Performance of ZnO Nanoparticles Synthesized by Microwave-assisted Process Using Zinc-Dust Waste as a Starting
Material
Pornapa Sujaridworakun1,2,a* and Kornkamol Natrchalayuth1,b
1Research Unit of Advanced Ceramic, Department of Materials Science, Faculty of Science, Chulalongkorn University, Phayathai, Patumwan, Bangkok, 10330 Thailand
2Center of Excellence on Petrochemical and Materials Technology, Chulalongkorn University, Bangkok, 10330 Thailand
apornapa.s@chula.ac.th, bk_kornkamol@hotmail.com
Keywords: microwave-assisted process, photocatalytic performance, ZnO, zinc-dust, waste
Abstract.
Materials and method Zn-dust waste derived from hot-dip galvanizing plant (Pacific Pipe Public Co., Ltd.) was used as starting materials.
Orel, Microwave-assisted non-aqueous synthesis of ZnO nanoparticles, Materials and technology, 45, 3 (2011) 173–177 [11] A.
Zeng, Facile microwave hydrothermal synthesis of zinc oxide one-dimensional nanostructure with three-dimensional morphology, Materials Science and Engineering B, 150 (2008) 187–193 [13] M.
Huang, Microwave synthesis and characterization of ZnO with various morphologies, Materials Letters, 62 (2008 ) 507–510
Materials and method Zn-dust waste derived from hot-dip galvanizing plant (Pacific Pipe Public Co., Ltd.) was used as starting materials.
Orel, Microwave-assisted non-aqueous synthesis of ZnO nanoparticles, Materials and technology, 45, 3 (2011) 173–177 [11] A.
Zeng, Facile microwave hydrothermal synthesis of zinc oxide one-dimensional nanostructure with three-dimensional morphology, Materials Science and Engineering B, 150 (2008) 187–193 [13] M.
Huang, Microwave synthesis and characterization of ZnO with various morphologies, Materials Letters, 62 (2008 ) 507–510
Online since: January 2025
Authors: Nicolò Lo Presti, Kamilia Abahri, Giovanni Castellazzi, Paolo Mengoli, Paolo Stabellini
Bio-based building materials are now being widely explored by researchers to promote their effective use and reduce the environmental impact of building construction.
Mechanical, hygric properties and the density were evaluated on the hardened materials for different tested formulations.
The most widespread types of insulating materials, however, come directly from the oil industry, such as expanded polystyrene or polyurethane foams.
Belarbi, “A review on recent research on bio-based building materials and their applications,” Aug. 01, 2023, Springer Science and Business Media Deutschland GmbH. doi: 10.1007/s40243-023-00234-7
Kavgic, “Mechanical, thermal, and moisture buffering properties of novel insulating hemp-lime composite building materials,” Materials, vol. 13, no. 21, pp. 1–18, Nov. 2020, doi: 10.3390/ma13215000
Mechanical, hygric properties and the density were evaluated on the hardened materials for different tested formulations.
The most widespread types of insulating materials, however, come directly from the oil industry, such as expanded polystyrene or polyurethane foams.
Belarbi, “A review on recent research on bio-based building materials and their applications,” Aug. 01, 2023, Springer Science and Business Media Deutschland GmbH. doi: 10.1007/s40243-023-00234-7
Kavgic, “Mechanical, thermal, and moisture buffering properties of novel insulating hemp-lime composite building materials,” Materials, vol. 13, no. 21, pp. 1–18, Nov. 2020, doi: 10.3390/ma13215000
Online since: April 2012
Authors: Xiu Li Fu, Yang Qiao, Xue Feng Yang
Mendez: Materials Science and Engineering A Vol. 399 (2005), p. 199-205
[2] W.
Bhadeshia: Materials Science and Engineering A Vol. 223 (1997), p. 64-77 [4] W.M.
Thomas: Metallurgical and Materials Transactions A Vol. 38A (2007), p. 1330-1336 [6] J.L.
Danninger: Journal of Materials Processing Technology Vol. 176 (2006), p. 62-69 [8] A.R.C.
Ridgway: Journal of Materials Processing Technology Vol. 200 (2008), p. 424-432 [9] HUANG Zhibin, ZHU Dongmei, LUO Fa, et al: Rare Metal Materials and Engineering Vol. 37 (2008), p.1411-1416
Bhadeshia: Materials Science and Engineering A Vol. 223 (1997), p. 64-77 [4] W.M.
Thomas: Metallurgical and Materials Transactions A Vol. 38A (2007), p. 1330-1336 [6] J.L.
Danninger: Journal of Materials Processing Technology Vol. 176 (2006), p. 62-69 [8] A.R.C.
Ridgway: Journal of Materials Processing Technology Vol. 200 (2008), p. 424-432 [9] HUANG Zhibin, ZHU Dongmei, LUO Fa, et al: Rare Metal Materials and Engineering Vol. 37 (2008), p.1411-1416
Online since: August 2013
Authors: Peng Liang, Jia Feng Wu, Yu Mei Zhao
Pure silica mesoporous materials possess a neutral framework, which limits their application in catalysis.
To obtain materials with potential for catalytic application, it is necessary to modify the nature of the amorphous walls by incorporation of heteroelements.
The red shift idicates that heteroatoms are incorporated into the framework of mesoporous materials and Si-O-M bonds were formed[6].
Pinnavaiat: Science Vol. 269 (1995), p. 1242 [2] Balasamy Rabindran Jermy, Sang-Yun Kim, Kanattukara Vijayan Bineesh and Manickam Selvaraj: Microporous and Mesoporous Materials Vol. 121(2009), p. 103 [3] Licheng Liu, Huiquan Li and Yi Zhang: Catalysis Today Vol.115(2006), p. 235 [4] F.
Montes: Microporous and Mesoporous Materials Vol. 122 (2009), p. 208 [12] Xuxu Wang, Haibing Xu, Xianzhi Fu, Ping Liu, Frédéric Lefebvre and Jean-Marie Basset: Journal of Molecular Catalysis A: Chemical Vol. 238 (2005), p. 185–191 [13] Yan Wang, Jinghong Ma, Dong Liang, Meimei Zhou, Fuxiang Li and Ruifeng Li: J Mater Sci Vol. 44 (2009), p. 6736 [14] Zhaoteng Xue, Tuo Zhang, Jinghong Ma, Haixia Miao, Weiming Fan, Yanyu Zhang and Ruifeng Li: Microporous and Mesoporous Materials Vol. 151 (2012), p. 271
To obtain materials with potential for catalytic application, it is necessary to modify the nature of the amorphous walls by incorporation of heteroelements.
The red shift idicates that heteroatoms are incorporated into the framework of mesoporous materials and Si-O-M bonds were formed[6].
Pinnavaiat: Science Vol. 269 (1995), p. 1242 [2] Balasamy Rabindran Jermy, Sang-Yun Kim, Kanattukara Vijayan Bineesh and Manickam Selvaraj: Microporous and Mesoporous Materials Vol. 121(2009), p. 103 [3] Licheng Liu, Huiquan Li and Yi Zhang: Catalysis Today Vol.115(2006), p. 235 [4] F.
Montes: Microporous and Mesoporous Materials Vol. 122 (2009), p. 208 [12] Xuxu Wang, Haibing Xu, Xianzhi Fu, Ping Liu, Frédéric Lefebvre and Jean-Marie Basset: Journal of Molecular Catalysis A: Chemical Vol. 238 (2005), p. 185–191 [13] Yan Wang, Jinghong Ma, Dong Liang, Meimei Zhou, Fuxiang Li and Ruifeng Li: J Mater Sci Vol. 44 (2009), p. 6736 [14] Zhaoteng Xue, Tuo Zhang, Jinghong Ma, Haixia Miao, Weiming Fan, Yanyu Zhang and Ruifeng Li: Microporous and Mesoporous Materials Vol. 151 (2012), p. 271
Online since: March 2016
Authors: Hong Tao Ni, Xin Wang, Luo Zhang, Xiao Yan Wang
Zhang, Optical Materials 36 (2014) 1506-1510
Lin, Journal of Materials Chemistry 21 (2011) 3686-3694
Isobe, Materials Letters 110 (2013) 180-183
Xu, Materials Research Bulletin 43 (2008) 2840-2849
Yuan, Journal of Materials Science: Materials in Electronics 21 (2010) 38-44
Lin, Journal of Materials Chemistry 21 (2011) 3686-3694
Isobe, Materials Letters 110 (2013) 180-183
Xu, Materials Research Bulletin 43 (2008) 2840-2849
Yuan, Journal of Materials Science: Materials in Electronics 21 (2010) 38-44
Online since: June 2020
Authors: Li Chuan Jin, Dainan Zhang, Miao Qing Wei
Journal of Material Science (45) 2010 5698
Solar Energy Materials and Solar Cells, (85) 2005
Journal of Materials Chemistry (10) 2000 2388-2391
Journal of Materials Science Letters (13) 1994 59
Journal of Vacuum Science & Technology B (23) 2005 499-506
Solar Energy Materials and Solar Cells, (85) 2005
Journal of Materials Chemistry (10) 2000 2388-2391
Journal of Materials Science Letters (13) 1994 59
Journal of Vacuum Science & Technology B (23) 2005 499-506