Sort by:
Publication Type:
Open access:
Publication Date:
Periodicals:
Search results
Online since: July 2019
This conference focused on advanced materials research in the forward-looking R&D domains where the intersection of key technologies in areas such as nano and micro-technology, biotechnology, stealth materials, smart materials and structures, and energy generation and storage is being explored.
He supervised 20 PhD and Pos-Doc scientific works and is member of the editorial board of several leading international scientific journals on composite and fibrous materials.
Previously, he worked as a Senior Researcher and Leader of Composite Materials at the Fibrous Materials Research Group (Fibrenamics), University of Minho, Portugal (2010-2018).
He has been invited to deliver keynote and invited talks in several international conferences and meetings focused on fibre science and composite materials.
Journal of Nanomaterials, Key Engineering Materials, International Journal of Polymer Science, Journal of Biobased Materials and Bioenergy, Advances in Polymer Technology, etc.) and is a potential reviewer for numerous scientific journals including Green Chemistry, Carbohydrate Polymers, Composite Science and Technology, Composites Part A & B, Dyes and Pigments, RSC Advances, Composite Interfaces, Journal of Composite Materials, Journal of Reinforced Plastics and Composites, Powder Technology, Journal of Nanomaterials, Journal of Applied Polymer Science, Fibres and Polymers, and so on.
He supervised 20 PhD and Pos-Doc scientific works and is member of the editorial board of several leading international scientific journals on composite and fibrous materials.
Previously, he worked as a Senior Researcher and Leader of Composite Materials at the Fibrous Materials Research Group (Fibrenamics), University of Minho, Portugal (2010-2018).
He has been invited to deliver keynote and invited talks in several international conferences and meetings focused on fibre science and composite materials.
Journal of Nanomaterials, Key Engineering Materials, International Journal of Polymer Science, Journal of Biobased Materials and Bioenergy, Advances in Polymer Technology, etc.) and is a potential reviewer for numerous scientific journals including Green Chemistry, Carbohydrate Polymers, Composite Science and Technology, Composites Part A & B, Dyes and Pigments, RSC Advances, Composite Interfaces, Journal of Composite Materials, Journal of Reinforced Plastics and Composites, Powder Technology, Journal of Nanomaterials, Journal of Applied Polymer Science, Fibres and Polymers, and so on.
Online since: September 2011
Authors: S.V. Hainsworth, H.V. Atkinson, Faraj Alshmri, S.D.A. Lawes
Samuel, "Production of Al-(12-25) wt% Si Alloys By Rapid Solidification: Melt Spinning Versus Centrifugal Atomization," Journal of Materials Science, vol. 27, pp. 3539-3551, 1992
Marino, "Structure and Stability of Rapidly Solidified Al-Si base Alloys," Journal of Materials Science Letters, vol. 5, pp. 586-588, 1986
Zalm, "Structural Inhomogeneties of AlSi Alloys Repidly Quenched from the Melt," Journal of Materials Science, vol. 17, pp. 2887-2894, 1982
Mahanti, "Characterizationof Rapidly Solidified Structures of Al-6Fe-3MM," Journal of Materials Science, vol. 26, pp. 4369-4374, 1991
Jones, "Structure and Properties of Rapidly Solidified Al Rich Al-Mn-si Alloys," Journal of Materials Science, vol. 34, pp. 735-747, 1999.
Marino, "Structure and Stability of Rapidly Solidified Al-Si base Alloys," Journal of Materials Science Letters, vol. 5, pp. 586-588, 1986
Zalm, "Structural Inhomogeneties of AlSi Alloys Repidly Quenched from the Melt," Journal of Materials Science, vol. 17, pp. 2887-2894, 1982
Mahanti, "Characterizationof Rapidly Solidified Structures of Al-6Fe-3MM," Journal of Materials Science, vol. 26, pp. 4369-4374, 1991
Jones, "Structure and Properties of Rapidly Solidified Al Rich Al-Mn-si Alloys," Journal of Materials Science, vol. 34, pp. 735-747, 1999.
Online since: September 2013
Authors: Marek Cieśla, Kazimierz Mutwil
Taking the foregoing into account, analyses that aim at determining the causes of crack formation and development should be conducted taking into account the knowledge of mechanics and materials science [5,6].
Mutwil, Degradation of cast steel parts working in power plant pipelines, Journal of Achievements in Materials and Manufacturing Engineering 18 (1-2) (2006) 219-222
Cieśla, Crack initiation in steel parts working under thermo-mechanical fatigue conditions, International Journal of Computational Materials Science and Surface Engineering (IJCMSSE) 1 (4) (2007) 424-437
Cieśla, Study on Cracking Process of Power Boiler Element, Production Editor, IOP Conference Series: Materials Science and Engineering 35 (2012) 012017 1-11
Junak, Low-cycle fatigue life of steel P92 under gradual loading, Production Editor, IOP Conference Series: Materials Science and Engineering 35 (2012) 012014 1-11
Mutwil, Degradation of cast steel parts working in power plant pipelines, Journal of Achievements in Materials and Manufacturing Engineering 18 (1-2) (2006) 219-222
Cieśla, Crack initiation in steel parts working under thermo-mechanical fatigue conditions, International Journal of Computational Materials Science and Surface Engineering (IJCMSSE) 1 (4) (2007) 424-437
Cieśla, Study on Cracking Process of Power Boiler Element, Production Editor, IOP Conference Series: Materials Science and Engineering 35 (2012) 012017 1-11
Junak, Low-cycle fatigue life of steel P92 under gradual loading, Production Editor, IOP Conference Series: Materials Science and Engineering 35 (2012) 012014 1-11
Online since: April 2014
Authors: Chen Kang Huang, Yun Ching Leong
The model is then used to predict the composite thermal conductivity for several composite materials.
Introduction For various purposes, various dopants are placed into matrix materials to form composite materials.
The enhancement of mechanical and/ or thermal properties is the main purpose of producing composite materials of this kind [1].
[3] J.P.Gwinn, R.L.Webb, Performance and testing of thermal interface materials, Microelectronics Journal, vol. 34, pp. 215-222, (2003)
[9] J.Wang, J.K.Carson, M.F.North, D.J.Cleland , A new approach to modelling the effective thermal conductivity of heterogeneous materials, International Journal of Heat and Mass Transfer, vol. 49, pp. 3075-3083
Introduction For various purposes, various dopants are placed into matrix materials to form composite materials.
The enhancement of mechanical and/ or thermal properties is the main purpose of producing composite materials of this kind [1].
[3] J.P.Gwinn, R.L.Webb, Performance and testing of thermal interface materials, Microelectronics Journal, vol. 34, pp. 215-222, (2003)
[9] J.Wang, J.K.Carson, M.F.North, D.J.Cleland , A new approach to modelling the effective thermal conductivity of heterogeneous materials, International Journal of Heat and Mass Transfer, vol. 49, pp. 3075-3083
Online since: February 2014
Authors: Jun Huai Xiang, Long Fa Jiang, Ling Yun Bai
Er3+ ions have been doped into many matrix materials, such as LiNbO3 [2], Al2O3 [3,4], Y2O3 [5].
Among the processes used to prepare hybrid materials, the sol-gel method has become more popular than others, because of very simple apparatus, low preparation temperature and also high purity of the elaborated materials [7].
These results indicated that the hybrid materials still represented the PL properties of Er3+.
Summary (1) Er0.5Ce0.5 (AA)3phen-doped TiO2/PMMA hybrid materials with PL spectra centered at 1.53 mm were prepared by the sol-gel method
Journal of Non-Crystalline Solids,1997,222: 272-281
Among the processes used to prepare hybrid materials, the sol-gel method has become more popular than others, because of very simple apparatus, low preparation temperature and also high purity of the elaborated materials [7].
These results indicated that the hybrid materials still represented the PL properties of Er3+.
Summary (1) Er0.5Ce0.5 (AA)3phen-doped TiO2/PMMA hybrid materials with PL spectra centered at 1.53 mm were prepared by the sol-gel method
Journal of Non-Crystalline Solids,1997,222: 272-281
Online since: November 2011
Authors: Li Li, Er Bao Liu, Zhen Li, Muhammad Iqbal Sabir, Wan Tao Guo
D.: Journal of Composite Materials Vol. 28 (1994), p.112
B.: Journal of Composite Materials Vol. 33 (1999), p. 1457-1469
:Journal of Composite Materials Vol. 28 (1994), p.1840-1854
:Mechanics of Advanced Materials and Structures, Vol.10 (2003),p. 43–75
:Development and Application of Materials, Vol. 14 (1992), p. 9-14.
B.: Journal of Composite Materials Vol. 33 (1999), p. 1457-1469
:Journal of Composite Materials Vol. 28 (1994), p.1840-1854
:Mechanics of Advanced Materials and Structures, Vol.10 (2003),p. 43–75
:Development and Application of Materials, Vol. 14 (1992), p. 9-14.
Online since: August 2011
Authors: Feng Yan Sun, Jian Jun Qu
It is one of the important materials which relates to motor energy conversion and service life.
Japanese Journal of Applied Physics. 1987, 26(1):197-199
Wear Properties and Life Prediction of Friction Materials for Ultrasonic Motors.
A Wear Evaluation Chart if Friction Materials Used for Ultrasonic Motors.
Wear and dynamic properties of piezoelectric ultrasonic motor with frictional materials coated stator, Materials Chemistry and Physics, 2005, 90:391~395 [7] Ding Qingjun.
Japanese Journal of Applied Physics. 1987, 26(1):197-199
Wear Properties and Life Prediction of Friction Materials for Ultrasonic Motors.
A Wear Evaluation Chart if Friction Materials Used for Ultrasonic Motors.
Wear and dynamic properties of piezoelectric ultrasonic motor with frictional materials coated stator, Materials Chemistry and Physics, 2005, 90:391~395 [7] Ding Qingjun.
Online since: November 2023
Authors: Mathieu Brochu, Priti Wanjara, Sila Atabay, Sheida Sarafan, Javad Gholipour, Josh Soost
Materials, 2022. 16(1): p. 1
Journal of Manufacturing and Materials Processing, 2022. 6(2): p. 30
Journal of Manufacturing and Materials Processing, 2021. 5(4): p. 107
Materials, 2020. 13(2): p. 418
Materials & Design, 2020. 193: p. 108818
Journal of Manufacturing and Materials Processing, 2022. 6(2): p. 30
Journal of Manufacturing and Materials Processing, 2021. 5(4): p. 107
Materials, 2020. 13(2): p. 418
Materials & Design, 2020. 193: p. 108818
Online since: June 2021
Authors: Lia-Nicoleta Botila, Gabriela-Victoria Mnerie, Emilia-Florina Binchiciu, Octavian Victor Oancă, Ion Aurel Perianu
However, a finer distribution of materials results in the case of ultrasound assistance.
Two variants of constructive solutions were conceived and realized (figure 4), which had as basic principle the application of ultrasound on the basic materials (on the pairs of materials that are welded).
Puicea, “Pulsed LASER-(micro)TIG hybrid welding: Process characteristics”, Journal of Materials Processing Technology, vol. 212(4), pg. 890-902; [3].
Wu - Material flow in ultrasonic vibration enhanced friction stir welding, Shandong University, Chi-nan-shih, Shandong Sheng, China, Journal of Materials Processing Technology, 11/2015; 225; [5].
Toma, Corneliu Craciunescu, Advanced materials joining using a hybrid ultrasonicelectric resistance technique, September 2010, Journal of Optoelectronics and Advanced Materials 12(9), pg. 1935-1941; [8].
Two variants of constructive solutions were conceived and realized (figure 4), which had as basic principle the application of ultrasound on the basic materials (on the pairs of materials that are welded).
Puicea, “Pulsed LASER-(micro)TIG hybrid welding: Process characteristics”, Journal of Materials Processing Technology, vol. 212(4), pg. 890-902; [3].
Wu - Material flow in ultrasonic vibration enhanced friction stir welding, Shandong University, Chi-nan-shih, Shandong Sheng, China, Journal of Materials Processing Technology, 11/2015; 225; [5].
Toma, Corneliu Craciunescu, Advanced materials joining using a hybrid ultrasonicelectric resistance technique, September 2010, Journal of Optoelectronics and Advanced Materials 12(9), pg. 1935-1941; [8].
Online since: May 2023
Authors: Hameed Naser, Sabah M. Mohammad, Nabeel Z. Al-Hazeem, Zainuriah Hassan
Introduction
Electrospinning is a plain and wide process for fabrication of an ultrafine fiber from various materials which include polymer, composite and ceramic.
The most preferred fiber/material in various applications is a fiber with a diameter within 10– 1000 nm in scale and soft surface morphology.
Ramkumar, Electrospinning of nanofibers, Journal of applied polymer science 96(2) (2005) 557-569
Al-Hardan, Amperometric room temperature hydrogen gas sensor based on the conjugated polymers of polypyrrole–polyethylene oxide nanofibers synthesised via electrospinning, Journal of Materials Science: Materials in Electronics 33(9) (2022) 7068-7078
Misra, Nanofibers: effective generation by electrospinning and their applications, Journal of Nanoscience and Nanotechnology 12(1) (2012) 1-25
The most preferred fiber/material in various applications is a fiber with a diameter within 10– 1000 nm in scale and soft surface morphology.
Ramkumar, Electrospinning of nanofibers, Journal of applied polymer science 96(2) (2005) 557-569
Al-Hardan, Amperometric room temperature hydrogen gas sensor based on the conjugated polymers of polypyrrole–polyethylene oxide nanofibers synthesised via electrospinning, Journal of Materials Science: Materials in Electronics 33(9) (2022) 7068-7078
Misra, Nanofibers: effective generation by electrospinning and their applications, Journal of Nanoscience and Nanotechnology 12(1) (2012) 1-25