Search results

Chen: Journal of Materials Science & Technology, Vol.22 (2006) No.03, p.342-344
Ma: Advanced materials Research, Vols.287-290 (2011), p.2302-2307
Xu: Journal of Alloys and Compounds, Vol.588 (2014), p.461-464
Lee: Journal of Alloys and Compounds, Vol.586 (2014), p.S348–S352
Qu: Journal of Harbin Bearing, Vol.34 (2013) No.2, p.101-103.

Acknowledgement This work was sponsored by Science Research Foundation of East Jiaotong University(No.01306016, No07JD06), Young Science Foundation of Jiangxi Provincial Education Office(09497), Young Science Foundation of Jiangxi Province（2009GQC0014）.
Wang: Journal of Nanchang University, vol. 23(3)(2001), p. 45
Li: Chinese Journal of Materials Re- search, vol.14 (3)(2000), p. 249
Zhong: Journal of Guangxi University, Vol. 26(4)(2001), p. 291
On Composite Materials, Florida(1992), in Press

Microstructure and Mechanical Properties of Nitrided and Chromized Short Steel Fiber Reinforced Aluminum based P/M Composites Sidharth Jain1a, Daniel Fabijanic2b, Kamlesh Chandra1, Vijaya Agarwala1 1Metallurgical and Materials Engineering Department, Indian Institute of Technology Roorkee, Roorkee- 247667, India 2Centre for Material and Fibre Innovation, Geelong Technology Precinct, Deakin University, Geelong, Victoria- 3217, Australia asidharthjai@gmail.com, bdaniel.fabijanic@deakin.edu.au Keywords: Metal Matrix Composites Nitriding, Chromizing, Compound Layer, Hardness, Powder Metallurgy, Sintering, Reaction Interface Abstract.
Bhagat, Journal of Materials Science (24), 1989, p. 1496-1502 [3] Y.
Lin and K.S.Liu, Journal of Material Science (32), 1997, p. 719-725 [4] R.C.
Agarwala V, Satyanaryana KG, Agarwala RC, Materials Science and Engineering A (270), 1999, p. 210-218 [6] G.Wang, P.
[7] Yoon BE, Kim MH, United States Patent No. 5523171, June 04, 1996 [8] Chung BG, Kim MH, United States Patent No. 55340483, July 09, 1996 [9] Mandal D, Dutta BK, Panigrahi SC, Journal of Materials Processing Technology (198), 2008, p. 195-201 [10] Mandal D, Dutta BK, Panigrahi SC, Materials Science and Engineering A (492), 2008, p. 346-352

Fatigue and Fracture of Engineering Materials and Structures 25 (2001), 755 - 764 [3] R.
Proc. of 16th International conference on composite materials, Kyoto, 2007 [5] A.
Ehrenstein, Polymeric Materials.
Encyclopedia of Materials: Science and Technology, 2001, 9444 - 9449 [12] M.
Materials Testing, 54 (2012), 750-755 [14] S.

Introduction Metal powders play an important role in the production of polymeric materials.
Metal powders can improve optical, mechanical [3], thermal [4] and electrical [5] properties of a polymer materials.
Materials and experimental procedures Acrilonitril butadiene styrene (ABS) was used as matrix components.
References [1] Zhu, K., Schmauder, S., Prediction of the failure properties of short fiber reinforced composites with metal and polymer matrix, Computational Materials Science, Vol. 28 (2003), p. 743
[9] Lux, F., Journal of Material Science, Vol. 18 (1999) p. 1457 [10] Krupa, I., Chodack, I., European Polymer Journal, Vol. 37 (2001) p. 2159

Fitzpatrick, Weld stress mapping using neutron and synchrotron x-ray diffraction, Materials Science Forum, 404-407 (2002) 599-604
Wagner, High-resolution neutron powder diffractometry on samples of small dimensions, Materials Sc.
Kang, Unconventional performance of a highly luminous strain/stress scanner for high resolution studies, Materials Sc.
Strunz, High-resolution strain/stress measurements by three-axis neutron diffractometer, Materials - MDPI, 13 (2020) 5449-5456
Springer Series in optical science, 137 (2008) 57-68.

Instrument & Materials COBB - P959302000 Bo absorbent tester, IGT printing performance analyzer, DCP-BKP10K smoothness instrument, the materials used in the test see table.1.
Salmen: Journal of Material Science, Vol. 37 (2002), p.151
Asrey: Journal of Applied Polymer Science, Vol.66 (1997), p.1789
Gane: Journal of Colloid and Interface Science Vol.252 (2002), p.373
Buyl: European Polymer Journal, Vol. 37 (2001), p.2385.

Allahkaram: Materials & Design, Vol.32(2011), p.133 [4] G.
Hazan: Journal of colloid and interface science,Vol.323(2008), p.293 [11] S.
Zarebidaki: Materials & Design, Vol.31(2010), p.3174 [14] M.
Ahmed: Materials Research Bulletin, Vol.44(2009), p.151 [16] J.N.
Zou: Materials Science and Engineering: A, Vol.426(2006), p.162

In this paper, we have inspected the structural morphology of novel composite materials - transition metal (TM) (Ni, Ti) / fullerene (C60) thin films, prepared at room temperature (RT) or 500°C, and modified by ion-irradiation and/or thermal annealing.
Introduction Metal-fullerene thin films (i.e., multilayers and mixtures) provide a rapidly developing class of interesting composite materials exhibiting attractive structural, mechanical, electronic and other properties [1-4]; some of them have already been utilized (e.g., in photoelectronics [5]).
Stadler: Journal of Alloys and Compounds 483 (2009), p. 374
Abe: Journal of Alloys and Compounds 509 (2011), p.
Miyashita: Journal of Chemical Physics 114 (2001), p. 9115

Introduction Sintered Nd-Fe-B permanent magnet materials are the third generation rare earth permanent magnetic materials following the cast and ferrite permanent magnets [1].
Nd-Fe-B permanent magnet materials is based on Nd2Fe14B matrix with the volume fraction of about 85% -97%, and the permanent magnet materials containing about 30% of rare earth elements (neodymium is about 90%).
Journal of Applied Physics, 1983, Vol.55(6), p. 2083-2087
Journal of Magnetism and Magnetic Materials, 1998, Vol.188(1-2), p. 125-137
Key Engineering Materials, 2001, 202-203(1-2) 407-410,2001 Trans Tech Publications, Switzerland.