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Fracture Behavior of AZ31-xCa (x=0, 0.7, 2.0 wt.%) Extrudes during Compression
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강나은 Na Eun Kang , 임창동 Chang Dong Yim , 유봉선 Bong Sun You , 박익민 Ik Min Park |
KJMM 48(1) 85-89, 2010 |
ABSTRACT
The plastic deformation behavior of magnesium alloy is affected simultaneously by deformation temperature and strain rate under warm and/or hot working conditions. The soundness of deformation of AZ31-xCa (x=0. 0.7, 2.0 wt.%) extrudes during compression was strongly affected by processing variables including deformation temperature, strain rate. compression-loading direction, which was related to the activation of available deformation systems. The deformation behavior of AZ31-xCa extrudes was also affected by Ca content, which was related to the change of the sort and fraction of second phase. The complex effects of deformation temperature and strain rate on the deformation behavior of AZ31-xCa extrudes during compression under various conditions could be successfully described by Zener-Hollomon parameter.
keyword : magnesium alloy, extrude, compression, soundness of deformation, processing window, Z parameter
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Microfabrication of Micro-Conductive patterns on Insulating Substrate by Electroless Nickel Plating
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이봉구 Bong Gu Lee , 문준희 Jun Hee Moon |
KJMM 48(1) 90-100, 2010 |
ABSTRACT
Micro-conductive patterns were microfabricated on an insulating substrate (SiO2) surface by a selective electroless nickel plating process in order to investigate the formation of seed layers. To fabricate micro-conductive patterns, a thin layer of metal (Cu.Cr) was deposited in the desired micropattern using laser-induced forward transfer (LIFT). and above this layer, a second layer was plated by selective electroless plating. The LIFT process. which was carried out in multi-scan mode, was used to fabricate micro-conductive patterns via electroless nickel plating. This method helps to improve the deposition process for forming seed patterns on the insulating substrate surface and the electrical conductivity of the resulting patterns. This study analyzes the effect of seed pattern formation by LIFT and key parameters in electroless nickel plating during micro-conductive pattern fabrication. The effects of the process variables on the cross-sectional shape and surface quality of the deposited patterns are examined using field emission scanning electron microscopy (FE-SEM) and an optical microscope.
keyword : Laser-induced forward transfer, LIFT, Laser direct writing, microdeposition, electroless nickel plating, seed Layer, micro-conductive pattern
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