Synthesis of Cu<sub>3</sub>Sn Alloy Nanocrystals through Sequential Reduction Induced by Gradual Increase of the Reaction Temperature

Cho, Sanghun; Shin, Dong-Sig; Yin, Zhenxing; Lee, Chaedong; Park, Si Yun; Yoo, Jeeyoung; Piao, Yuanzhe; Kim, Youn Sang

doi:10.1002/chem.201406154

Cited by 7 publications

(5 citation statements)

References 36 publications

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“…If continuously increasing n CuCl 2 ⋅ 2 H 2 O to 10 mmol (line f), impurity of metallic Cu increased. Previous study on the evolution of Cu 6 Sn 5 to Cu 3 Sn is basically dependent on the control of temperature or aging time: lower temperature tends to form Cu 6 Sn 5 , whereas a higher temperature is more likely to produce Cu 3 Sn . If the temperature remains unchanged, Cu 6 Sn 5 is initially formed and then comes to Cu 3 Sn, because Cu 6 Sn 5 grows much faster than Cu 3 Sn .…”

Section: Resultsmentioning

confidence: 99%

“…processes . With these synthetic routes, well‐defined monodisperse Sn−Cu, Pt 3 Sn, and Sn−Sb, etc., nano‐intermetallic compounds have been synthesized successfully. Unfortunately, an important restriction on the fabrication of monodisperse particles lies in the strict condition and utilization of toxic organic capping agents, solvents, reducing agents, and organo‐metals.…”

Section: Introductionmentioning

confidence: 99%

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Smart Solution Chemistry to Sn‐Containing Intermetallic Compounds through a Self‐Disproportionation Process

Zhang

et al. 2016

Chemistry A European J

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Developing new methods to synthesize intermetallics is one of the most critical issues for the discovery and application of multifunctional metal materials; however, the synthesis of Sn-containing intermetallics is challenging. In this work, we demonstrated for the first time that a self-disproportionation-induced in situ process produces cavernous Sn-Cu intermetallics (Cu3 Sn and Cu6 Sn5 ). The successful synthesis is realized by introducing inorganic metal salts (SnCl2 ⋅2 H2 O) to NaOH aqueous solution to form an intermediate product of reductant (Na2 SnO2 ) and by employing steam pressures that enhance the reduction ability. Distinct from the traditional in situ reduction, the current reduction process avoided the uncontrolled phase composition and excessive use of organic regents. An insight into the mechanism was revealed for the Sn-Cu case. Moreover, this method could be extended to other Sn-containing materials (Sn-Co, Sn-Ni). All these intermetallics were attempted in the catalytic effect on thermal decompositions of ammonium perchlorate. It is demonstrated that Cu3 Sn showed an outstanding catalytic performance. The superior property might be primarily originated from the intrinsic chemical compositions and cavernous morphology as well. We supposed that this smart solution reduction methodology reported here would provide a new recognition for the reduction reaction, and its modified strategy may be applied to the synthesis of other metals, intermetallics as well as some unknown materials.

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Section: Resultsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Smart Solution Chemistry to Sn‐Containing Intermetallic Compounds through a Self‐Disproportionation Process

Zhang

et al. 2016

Chemistry A European J

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“…In addition to the desired alloy, few more diffraction peaks at 2θ = 43.2 o , 50.4 o and 74.1 o were noticeable, which can be indexed as cubic symmetry of pure Cu element (#JCPDS card 04-0836). The presence of Cu element can be attributed to the early formation of Cu during the thermal reduction as the Cu 2+ has high positive reduction potential of 0.34 V [12]. In addition, possibility of SnO formation was also analysed; the reference peak positions as shown in the Figure 1b, for pure SnO tetragonal symmetry (#JCPDS card 072-1012) did not match with the XRD pattern of as-synthesised material, confirming absence SnO in the material.…”

Section: Characterization Of Cu-sn and Orr Performancementioning

confidence: 99%

Application of Low-Cost Cu–Sn Bimetal Alloy as Oxygen Reduction Reaction Catalyst for Improving Performance of the Microbial Fuel Cell

et al. 2018

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In this experiment, a new bimetal low–cost Cu–Sn alloy was synthesized and it was tested as catalyst for oxygen reduction reaction (ORR) in MFC and the results were compared with the commercially available Pt-C catalyst. Cyclic voltammetry for evaluating ORR of the test cathode containing Cu-Sn catalysts under oxygen saturated environment displayed large ORR current peak, showing less overpotential demand for ORR. Maximum power density of 457 mW/m2 obtained from MFC using Cu–Sn catalyst, was found to be slightly higher than the power density of 446 mW/m2 demonstrated by MFC using Pt based cathode. Biochemical conversion of organic matter to direct electric current in Cu–Sn based MFC occurred at a coulombic efficiency of 55.8%, while demonstrating 92% of chemical oxygen demand removal. This study demonstrated application of low cost Cu–Sn bimetal alloy as excellent ORR catalyst in MFC and would be very helpful to commission larger MFCs for field applications to harvest energy in the form of direct electricity from wastewaters while offering wastewater treatment.

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“…However, there is no report about the direct Cu–Cu bonding using the nano-Cu 3 Sn/PEG-400 composite paste so far, let alone about investigating the microstructure and mechanical properties of the full-Cu 3 Sn joints. At present, Cu 3 Sn IMCs are mainly prepared through heat treatment − and a thermal decomposition reaction. , For instance, a Cu 3 Sn IMC film was obtained by magnetron sputtering, electroplatingm or electroless-plating of Sn on Cu foil and then heating above 200 °C for even more than 24 h. Other researchers have used the thermal decomposition of expensive metal organic salts Sn(acac) 2 and Cu(acac) 2 to prepare the Cu 3 Sn IMC NPs. , Unfortunately, these preparation methods have their own limitations, such as a long process time, a high process temperature, and environmental pollution.…”

Section: Introductionmentioning

confidence: 99%

“…44,45 For instance, a Cu 3 Sn IMC film was obtained by magnetron sputtering, 41 electroplatingm 42 or electroless-plating 43 of Sn on Cu foil and then heating above 200 °C for even more than 24 h. Other researchers have used the thermal decomposition of expensive metal organic salts Sn(acac) 2 and Cu(acac) 2 to prepare the Cu 3 Sn IMC NPs. 44,45 Unfortunately, these preparation methods have their own limitations, such as a long process time, a high process temperature, and environmental pollution.…”

Section: ■ Introductionmentioning

confidence: 99%

Robust Cu–Cu Bonding with Multiscale Coralloid Nano-Cu₃Sn Paste for High-Power Electronics Packaging

Guo

Liu

et al. 2022

ACS Appl. Electron. Mater.

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In this work, a multiscale coralloid nano-Cu3Sn composed of a bimodal structure (∼55 and ∼120 nm) has been successfully synthesized to meet low-cost and Pb-free packaging demands for high-power electronic application. Owing to the excellent oxidation resistance of the Cu3Sn intermetallic compounds (IMCs) and the protection of solvent poly(ethylene glycol)-400 (PEG-400) at high temperature, the full-Cu3Sn joints sintered in air have a comparative shear strength with the joints acquired in vacuum when the sintering temperature is no more than 300 °C. The full-Cu3Sn joints acquired at 300 °C in air achieve a high bonding strength of 40.4 MPa, which is superior to those of traditional Sn-based solder joints (19 MPa) and full-Cu6Sn5 joints (17.7 MPa). The electrical resistivity of the sintered Cu3Sn films reaches 29.1 μΩ·cm in air. Cu3.02Sn0.98 is formed at the interface between the Cu substrate and sintered Cu3Sn layer, contributing to the exceptional bonding strength of the full-Cu3Sn joints. The bonding strength of the joints after high-temperature storage (HTS) tests reveals that the prepared full-Cu3Sn joints possess outstanding long-term thermal stability with a shear strength of 47.9 MPa after 800 h of storage at 250 °C. Our work breaks through the synthesis bottleneck of nano-Cu3Sn IMCs and provides the underlying insights needed to guide the design of highly stable full-IMC joints for high-temperature electronic packaging.

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Synthesis of Cu₃Sn Alloy Nanocrystals through Sequential Reduction Induced by Gradual Increase of the Reaction Temperature

Cited by 7 publications

References 36 publications

Smart Solution Chemistry to Sn‐Containing Intermetallic Compounds through a Self‐Disproportionation Process

Smart Solution Chemistry to Sn‐Containing Intermetallic Compounds through a Self‐Disproportionation Process

Application of Low-Cost Cu–Sn Bimetal Alloy as Oxygen Reduction Reaction Catalyst for Improving Performance of the Microbial Fuel Cell

Robust Cu–Cu Bonding with Multiscale Coralloid Nano-Cu₃Sn Paste for High-Power Electronics Packaging

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Synthesis of Cu3Sn Alloy Nanocrystals through Sequential Reduction Induced by Gradual Increase of the Reaction Temperature

Cited by 7 publications

References 36 publications

Smart Solution Chemistry to Sn‐Containing Intermetallic Compounds through a Self‐Disproportionation Process

Smart Solution Chemistry to Sn‐Containing Intermetallic Compounds through a Self‐Disproportionation Process

Application of Low-Cost Cu–Sn Bimetal Alloy as Oxygen Reduction Reaction Catalyst for Improving Performance of the Microbial Fuel Cell

Robust Cu–Cu Bonding with Multiscale Coralloid Nano-Cu3Sn Paste for High-Power Electronics Packaging

Contact Info

Product

Resources

About

Synthesis of Cu₃Sn Alloy Nanocrystals through Sequential Reduction Induced by Gradual Increase of the Reaction Temperature

Robust Cu–Cu Bonding with Multiscale Coralloid Nano-Cu₃Sn Paste for High-Power Electronics Packaging