Solidification behaviors of undercooled Ni-P alloys

Qi-Sen, Huang; Li, Liu; Xiu-Xun, Wei; Li, Jin-Fu

doi:10.7498/aps.61.166401

Cited by 4 publications

(1 citation statement)

References 20 publications

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“…Cryogenic treatment can not only increase the properties of metal materials, extend the service life of parts and simple non-polluting, but also reveal the organization's evolution and the relationship between microstructure and properties after the cryogenic treatment of metal materials. Accordingly, the research about the cryogenic treatment of metal materials has attracted extensive attention of many researchers [1][2][3][4]. The investigation about the cryogenic treatment of copper alloy has been more, and these studies mainly focus on the cryogenic treatment which applied in microstructure and properties [5][6][7], but few reports were about solid-state phase transformation of copper alloy after cryogenic treatment, because the solid phase transformation of copper alloys affects the final microstructure and properties.…”

Section: Introductionmentioning

confidence: 99%

Transformation Kinetics of α+γ<sub>2</sub> to ß in Cu-Al Alloy after Cryogenic Treatment

et al. 2012

AMR

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The transformation temperature and time of α+γ2 to ß in a Cu-Al alloy after cryogenic treatment during heating were measured by DSC, and the transformation activation energy of α+γ2 to ß was also calculated. It is indicated that the Cu-Al alloy with heating rate of 10°C/min, the phase transformation onset and ending temperature is 561.75°C and 582.88°C, respectively, and the phase transformation time is126.6S. The phase transformation activation energy decreases with the increasing volume fraction of their phase transformation.

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Section: Introductionmentioning

confidence: 99%

Transformation Kinetics of α+γ<sub>2</sub> to ß in Cu-Al Alloy after Cryogenic Treatment

et al. 2012

AMR

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A Review on Phase Field Modeling for Formation of η-Cu6Sn5 Intermetallic

Sun

Zhao

Liang

et al. 2022

Metals

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Formation of intermetallic compounds (IMCs) exhibits remarkable microstructural features and provides opportunities for microstructure control of microelectronic interconnects. Excessive formation of brittle IMCs at the Cu/Sn interface such as η-Cu6Sn5 can deteriorate the reliability and in turn lead to solder joint failure in the Pb-free Sn-based solder joints. Phase field method is a versatile tool for prediction of the mesoscopic structure evolution in solders, which does not require tracking interfaces. The relationships between the microstructures, reliability and wettability were widely investigated, and several formation and growth mechanisms were also proposed for η-Cu6Sn5. In this paper, the current research works are reviewed and the prospective of the application of phase field method in the formation of η-Cu6Sn5 are discussed. Combined phase field simulations hold great promise in modeling the formation kinetics of IMCs with complex microstructural and chemical interactions.

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Lamellarrod transition mechanism under high growth velocity condition

Wang¹,

Wang²,

Lin³

et al. 2013

Acta Phys. Sin.

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At a low velocity, the lamellarrod eutectic transition can be controlled by the volume fraction of one eutectic phase only. The factors which affect this kind of transition at high growth velocities are not clear. Based on the competitive growth rule, the criterion for lamellarrod transition is obtained by combining the models of lamellar and rod eutectic growth under rapid solidification conditions. It is shown that for a certain volume fraction, if its value fluctuates around the critical point predicted by the JH Jackson and Hunt model, the increase of the growth velocity or the partition coefficient will lead to the rodlamellar transition. Otherwise, no transition will take place. The lamellarrod eutectic transition at high growth velocity is controlled by the volume fraction variation, which is caused by the increase of the growth velocity.

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Solidification behaviors of undercooled Ni-P alloys

Cited by 4 publications

References 20 publications

Transformation Kinetics of α+γ<sub>2</sub> to ß in Cu-Al Alloy after Cryogenic Treatment

Transformation Kinetics of α+γ<sub>2</sub> to ß in Cu-Al Alloy after Cryogenic Treatment

A Review on Phase Field Modeling for Formation of η-Cu6Sn5 Intermetallic

Lamellarrod transition mechanism under high growth velocity condition

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