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Online since: February 2015
Authors: Ahmad Kamil Fakhruddin Mokhtar, Hasmaliza Mohamad
Performance of Rutile as an Antibacterial Material in Ceramic Tiles
HASMALIZA Mohamada* and AHMAD KAMIL FAKHRUDDIN Mohd Mokhtarb
Structural Materials Niche Area, School of Materials and Mineral Resources Engineering,
Universiti Sains Malaysia Engineering Campus, 14300 Nibong Tebal, Penang, Malaysia.
Because of the growing demand for healthy living, there is a keen interest in materials capable of killing harmful microorganisms.
Many inorganic antibacterial materials have been developed to prevent bio-infectious diseases.
Experimental Green porcelain body was prepared by drying a mixture of raw materials at 100°C for 4 hours followed by milling (5 hours) and sieving.
Journal of Materials Engineering and Performance, (2009), 19(3), 374–379. doi:10.1007/s11665-009-9490-y [4] Bonetta, S., Bonetta, S., Motta, F., Strini, A., & Carraro, E., Photocatalytic bacterial inactivation by TiO2-coated surfaces.
Because of the growing demand for healthy living, there is a keen interest in materials capable of killing harmful microorganisms.
Many inorganic antibacterial materials have been developed to prevent bio-infectious diseases.
Experimental Green porcelain body was prepared by drying a mixture of raw materials at 100°C for 4 hours followed by milling (5 hours) and sieving.
Journal of Materials Engineering and Performance, (2009), 19(3), 374–379. doi:10.1007/s11665-009-9490-y [4] Bonetta, S., Bonetta, S., Motta, F., Strini, A., & Carraro, E., Photocatalytic bacterial inactivation by TiO2-coated surfaces.
Online since: September 2014
Authors: Bang Sheng Xing, Le Xu
It builds a sample variable space partitioning model according to the original materials’ tensile strength.
During the cold rolling process, original materials are subjected to repeated rolling deal, and subjected to an integrated complex constraint.
Dividing Variable Space according to Original Materials’ Tensile Strength When predicting the mechanical performance of cold rolled ribbed steel bars, if it builds a RBP neural network prediction model in the whole space range of original materials’ tensile strength, which equivalent of solving global extreme of nonlinear function between the original materials’ tensile strength and product performance parameters, it is likely to fall into local extreme and causes the fail of network’s training.
Luo: Optimization Theory Methods and Solving Software (Science Press, China 2006) (In Chinese) [4] X.H.
Wang: Chinese Journal of Chemical Engineering, (2007) No.2, pp. 240-246.
During the cold rolling process, original materials are subjected to repeated rolling deal, and subjected to an integrated complex constraint.
Dividing Variable Space according to Original Materials’ Tensile Strength When predicting the mechanical performance of cold rolled ribbed steel bars, if it builds a RBP neural network prediction model in the whole space range of original materials’ tensile strength, which equivalent of solving global extreme of nonlinear function between the original materials’ tensile strength and product performance parameters, it is likely to fall into local extreme and causes the fail of network’s training.
Luo: Optimization Theory Methods and Solving Software (Science Press, China 2006) (In Chinese) [4] X.H.
Wang: Chinese Journal of Chemical Engineering, (2007) No.2, pp. 240-246.
Online since: January 2011
Authors: V. Swaminathan, M. Jayachandran, L.C. Nehru, C. Sanjeeviraja
Mulla, Journal of Materials Science Letters 19 (2000) 249– 252
[90] J.
Logana, Journal of Hazardous Materials 178 (2010) 29
XIAO, Materials Science-Poland, 26(3) (2008) 517
Li, Materials Science and Engineering A 426 (2006) 274
Morante, Materials Science and Engineering C 15 (2001) 203
Logana, Journal of Hazardous Materials 178 (2010) 29
XIAO, Materials Science-Poland, 26(3) (2008) 517
Li, Materials Science and Engineering A 426 (2006) 274
Morante, Materials Science and Engineering C 15 (2001) 203
Online since: April 2022
Authors: Ramachandran Velmurugan, Mahesh Unnam, Shanmugam Kumar
Chemical Structure of the materials used for the preparation of the novel shape memory polymer.
Wu., “Infrared Light-Active Shape Memory Polymer Filled with Nanocarbon Particles”, Journal of Applied Polymer Science,114: 2455-2460, 2009
Review of progress in shape-memory polymers, Journal of materials chemistry, 17 (2007) 1543-1558
[8] Hu, J., and Chen, S., A review of actively moving polymers in textile applications, Journal of Materials Chemistry, 20 (2010) 3346–3355
Journal of Intelligent Material Systems and Structures,26 (2018) 2164-2176
Wu., “Infrared Light-Active Shape Memory Polymer Filled with Nanocarbon Particles”, Journal of Applied Polymer Science,114: 2455-2460, 2009
Review of progress in shape-memory polymers, Journal of materials chemistry, 17 (2007) 1543-1558
[8] Hu, J., and Chen, S., A review of actively moving polymers in textile applications, Journal of Materials Chemistry, 20 (2010) 3346–3355
Journal of Intelligent Material Systems and Structures,26 (2018) 2164-2176
Online since: October 2012
Authors: Hyun Do Yun, Ju Ne Su Kim
These characteristics of SHCC materials improve crack-damage mitigation.
Current application of SHCC materials includes bridge decks, building dampers, retaining wall, and irrigation channels.
In this study, an expansive admixture was utilized for SHCC mixture to control the shrinkage of SHCC materials.
Test Results and Discussion 3.1 Tensile Strength of SHCC materials (a)Test setup (b) Stress-strain relationship curve (c) PE30 (d) EX-PE30 Figure 4.
Li, "Development of Flexural Composite Properties and Dry Shrinkage Behavior of High-Performance Fiber Reinforced Cementitious Composites at Early Ages", ACI Materials Journal, Vol. 96, No. 1, pp20-26, 1999 [4] Young-Oh Lee and Hyun-Do Yun, “Effect of Expansive admixture on the mechanical properties of Strain-Hardening Cement Composite (SHCC)”, Journal of the Korea Concrete Institute, Vol. 22, No. 5, pp. 617-624, (2010)
Current application of SHCC materials includes bridge decks, building dampers, retaining wall, and irrigation channels.
In this study, an expansive admixture was utilized for SHCC mixture to control the shrinkage of SHCC materials.
Test Results and Discussion 3.1 Tensile Strength of SHCC materials (a)Test setup (b) Stress-strain relationship curve (c) PE30 (d) EX-PE30 Figure 4.
Li, "Development of Flexural Composite Properties and Dry Shrinkage Behavior of High-Performance Fiber Reinforced Cementitious Composites at Early Ages", ACI Materials Journal, Vol. 96, No. 1, pp20-26, 1999 [4] Young-Oh Lee and Hyun-Do Yun, “Effect of Expansive admixture on the mechanical properties of Strain-Hardening Cement Composite (SHCC)”, Journal of the Korea Concrete Institute, Vol. 22, No. 5, pp. 617-624, (2010)
Online since: March 2016
Authors: Zhong Ji, Chao Zheng, Jie Fu, Yun Hu Zhu
School of Materials Science and Engineering, Shandong University, 17923 Jingshi Road, Jinan, 250061, China
jizhong@sdu.edu.cn
Keywords: Zr-based metallic glass, Laser shock peening, Surface roughness.
Feng, et al, Homogeneous viscous flow behavior of a Cu-Zr based bulk metallic glass composites, Materials Science and Engineering A. 620 (2015) 352-358
Wang, The elastic properties, elastic models and elastic perspectives of metallic glasses, Progress in Materials Science. 57 (2012) 487-656
Woodward, et al, Effects of fatigue and fretting on residual stresses introduced by laser shock peening, Materials Science and Engineering A. 435-346 (2006) 12-18
Jeong, et al, Enhancement of abrasion and corrosion resistance of duplex stainless steel by laser shock peening, Journal of Materials Processing Technology. 212 (2012) 1347-1354
Feng, et al, Homogeneous viscous flow behavior of a Cu-Zr based bulk metallic glass composites, Materials Science and Engineering A. 620 (2015) 352-358
Wang, The elastic properties, elastic models and elastic perspectives of metallic glasses, Progress in Materials Science. 57 (2012) 487-656
Woodward, et al, Effects of fatigue and fretting on residual stresses introduced by laser shock peening, Materials Science and Engineering A. 435-346 (2006) 12-18
Jeong, et al, Enhancement of abrasion and corrosion resistance of duplex stainless steel by laser shock peening, Journal of Materials Processing Technology. 212 (2012) 1347-1354
Online since: October 2010
Authors: Shahrum Abdullah, T.E. Putra, S.N. Sahadan, K.O. Willis, Zulkifli Mohd Nopiah, Mohd Noor Baharin
The ability to shorten a signal is crucial to allow investigation of the data in a more time efficient manor and is therefore a valuable tool for analysis of properties in materials [4].
Nuawi, A Study of Fatigue Data Editing using the Short- Time Fourier Transform (STFT), American Journal of Applied Sciences, 6(4), pp.565- 575 (2009) [3] Z.
Nopiah: Fatigue Road Signal Denoising Process Using the 4th Order of Daubechies Wavelet Transforms, Journal of Applied Sciences, Vol. 8 (14), pp. 2496-2509 (2008)
Nopiah: Wavelet Coefficient Extraction Algorithm for Extracting Fatigue Features in Variable Amplitude Fatigue Loading, Journal of Applied Sciences, Vol. 10 (4), pp. 277-283 (2010)
Topper: A Stress Strain Function for the Fatigue of Metals, Journal of Materials, Vol. 5, pp.767-776 (1970).
Nuawi, A Study of Fatigue Data Editing using the Short- Time Fourier Transform (STFT), American Journal of Applied Sciences, 6(4), pp.565- 575 (2009) [3] Z.
Nopiah: Fatigue Road Signal Denoising Process Using the 4th Order of Daubechies Wavelet Transforms, Journal of Applied Sciences, Vol. 8 (14), pp. 2496-2509 (2008)
Nopiah: Wavelet Coefficient Extraction Algorithm for Extracting Fatigue Features in Variable Amplitude Fatigue Loading, Journal of Applied Sciences, Vol. 10 (4), pp. 277-283 (2010)
Topper: A Stress Strain Function for the Fatigue of Metals, Journal of Materials, Vol. 5, pp.767-776 (1970).
Online since: November 2013
Authors: Cena Dimova
Synthetic resorbable materials were intended as an inexpensive substitute for natural bone.
Materials for bone tissue substitutions Various materials are used in modern dental and maxillofacial surgery for bone tissue substitution and reconstruction.
Synthetic resorbable materials were intended as an inexpensive substitute for natural bone.
The development of new medical technologies enables use of achievements in material science, biochemistry, molecular biology and genetic engineering while creating new combined synthetic materials for bone grafting (osteoplasty).
The Open Dentistry Journal 2011;(5): 96-104
Materials for bone tissue substitutions Various materials are used in modern dental and maxillofacial surgery for bone tissue substitution and reconstruction.
Synthetic resorbable materials were intended as an inexpensive substitute for natural bone.
The development of new medical technologies enables use of achievements in material science, biochemistry, molecular biology and genetic engineering while creating new combined synthetic materials for bone grafting (osteoplasty).
The Open Dentistry Journal 2011;(5): 96-104
Online since: April 2021
Authors: Lyudmila G. Kolyada, Elena V. Tarasyuk, A.V. Smirnova
Development of New Composite Materials from Tetra Pak Packaging Waste
L.G.
Karaboyaci, Process design for the recycling of Tetra Pak components, European Journal of Engineering and Natural Sciences. 2 (2017) 126-129
Journal of Thermoplastic Composite Materials. 29 (2016) 1601-1610
Science progress. 101 (2018) 161-170
Derkach, Processing of combined materials containers and packages, Container and packing. 1 (2004) 25-26
Karaboyaci, Process design for the recycling of Tetra Pak components, European Journal of Engineering and Natural Sciences. 2 (2017) 126-129
Journal of Thermoplastic Composite Materials. 29 (2016) 1601-1610
Science progress. 101 (2018) 161-170
Derkach, Processing of combined materials containers and packages, Container and packing. 1 (2004) 25-26
Online since: July 2017
Authors: Valeriy Ivanovich Platonov, Evgeniya Vitalievna Leonova, Sergey Nikolaevich Larin
Materials Science and Engineering: A.
Materials Science and Engineering: A.
Materials Science and Engineering: A.
Materials Science and Engineering: A.
Journal of Materials Processing Technology Volume 72, Issue 3: 429-433
Materials Science and Engineering: A.
Materials Science and Engineering: A.
Materials Science and Engineering: A.
Journal of Materials Processing Technology Volume 72, Issue 3: 429-433