Thermodynamic Description of the Quaternary Ag-Cu-In-Sn System

Gierlotka, Wojciech

doi:10.1007/s11664-011-1757-z

Cited by 29 publications

(15 citation statements)

References 77 publications

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“…The experimental results [18][19][20][21][22][23][24][25][26][27] summarized in Table 1 do not include the stable ternary intermetallic compounds. According to the thermodynamic calculations of the Ag-Cu-Sn ternary system [21,24,25,28], thermodynamic properties of the ternary liquid alloys were not considered in the calculated results of Moon et al [21], Ohnuma et al [24] and Yen et al [25], while the isothermal sections and vertical sections of phase relations calculated by Gierlotka et al [28] were obviously different from the determined experimental results [18,[24][25][26][27]. The liquidus projection of the Ag-Cu-Sn ternary system in the Ag-Cu-rich part was studied experimentally by Gebhardt et al [18].…”

Section: The Ag-cu-sn Ternary Systemmentioning

confidence: 99%

“…Experimental studies and thermodynamic calculations of phase equilibria of the Ag-Cu-Sn ternary system were performed [18][19][20][21][22][23][24][25][26][27][28][29]. Gebhardt et al [18] systematically conducted the experimental study of the Ag-Cu-Sn ternary system.…”

Section: Introductionmentioning

confidence: 99%

“…Several isothermal sections and vertical sections of the Ag-Cu-Sn ternary system were determined by Ohnuma et al [24], Yen et al [25], Marjanovic et al [26] and Fima et al [27]. Based on the experimental results, the Ag-Cu-Sn ternary system was calculated by Moon et al [21], Ohnuma et al [24], Yen et al [25], Gierlotka et al [28] and the unpublished COST 531 Database for Lead-free Solders [29]. Recently, Luef et al [30] experimentally determined the mixing enthalpy of the liquid phase in the Ag-Cu-Sn ternary system, and Kopyto et al [31] experimentally determined the activity of Sn in the liquid phase, which was not considered in these thermodynamic calculations of the Ag-Cu-Sn ternary system reported by [21,24,25].…”

Section: Introductionmentioning

confidence: 99%

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Thermodynamic Modeling of the Ag-Cu-Sn Ternary System

Tong

Rong

et al. 2022

Metals

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In this work, combined with previous assessments of the Ag-Cu, Ag-Sn and Cu-Sn binary systems, thermodynamic modeling of the Ag-Cu-Sn ternary system was performed using the CALPHAD method using the reported phase diagram data and thermodynamic data. The solution phases including Liquid, fcc, bcc, hcp, bct(Sn) and diamond(Sn) were modeled as substitutional solutions and their excess Gibbs energies were expressed by the Redlich–Kister–Muggianu polynomial. The solubility of the third element in binary intermetallic compounds was not taken into account due to the fact that ternary solubilities for most of the binary compounds are not significant. Thermodynamic properties of liquid alloys, liquidus projection, several vertical sections and isothermal sections were calculated, which were in reasonable agreement with the reported experimental data. Finally, a set of self-consistent thermodynamic parameters formulating the Gibbs energies of various phases in the Ag-Cu-Sn ternary system was obtained.

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Section: The Ag-cu-sn Ternary Systemmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Thermodynamic Modeling of the Ag-Cu-Sn Ternary System

Tong

Rong

et al. 2022

Metals

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“…Moreover, the formation and evolution of microstructures is examined by utilizing thermodynamic calculations. [45][46][47] The stabilizing effect (i.e. the higher (more negative) value for Gibbs energy of formation) of In on Cu-Sn IMCs of Cu 6 Sn 5 and Cu 3 Sn is analysed and the effects on chemical potentials and driving forces diffusion are discussed.…”

Section: Introductionmentioning

confidence: 99%

“…the higher (more negative) value for Gibbs energy of formation) of In on Cu-Sn IMCs of Cu 6 Sn 5 and Cu 3 Sn is analysed and the effects on chemical potentials and driving forces diffusion are discussed. 46,47…”

Section: Introductionmentioning

confidence: 99%

Wafer Level Solid Liquid Interdiffusion Bonding: Formation and Evolution of Microstructures

Vuorinen

Dong

Ross

et al. 2020

Journal of Elec Materi

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Wafer-level solid liquid interdiffusion (SLID) bonding, also known as transient liquid-phase bonding, is becoming an increasingly attractive method for industrial usage since it can provide simultaneous formation of electrical interconnections and hermetic encapsulation for microelectromechanical systems. Additionally, SLID is utilized in die-attach bonding for electronic power components. In order to ensure the functionality and reliability of the devices, a fundamental understanding of the formation and evolution of interconnection microstructures, as well as global and local stresses, is of utmost importance. In this work a low-temperature Cu-In-Sn based SLID bonding process is presented. It was discovered that by introducing In to the traditional Cu-Sn metallurgy as an additional alloying element, it is possible to significantly decrease the bonding temperature. Decreasing the bonding temperature results in lower CTE induced global residual stresses. However, there are still several open issues to be studied regarding the effects of dissolved In on the physical properties of the Cu-Sn intermetallics. Additionally, partially metastable microstructures were observed in bonded samples that did not significantly evolve during thermal annealing. This indicates the Cu-In-Sn SLID bond microstructure is extremely stable.

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