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Investigation of Ceramics Admixtured with Waste Sludge from Lead Electroplating

Tadeusz Stefanowicz Małgorzata Osińska Stefania Napieralska-Zagozda
Archives of Environmental Protection | 2000 | vol. 26 | No 3 | 137-149
Keywords ceramics admixture electroplating sludge lead
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Abstract

Clay was admixtured with 1, 2, 3 and 10% of waste sludge precipitated from lead electroplating fluoroborate electrolyte. The sludge contained, besides 60.7% of lead, 3.7% of fluorine. Small standardized ceramic bricks were burnt at 980°C and then tested for physical and mechanical features (contraction, water soaking, freeze resistance, compressive strength) and for leaching with water saturated with carbon dioxide. The tests showed that 1% of added sludge did not change properties of ceramic bricks and leaching of lead and fluorine is not hazardous, while the larger admixtures result in spoiling of quality features. On burning fluorine is emitted to exhaust gases.
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Authors and Affiliations

Tadeusz Stefanowicz
Małgorzata Osińska
Stefania Napieralska-Zagozda

Effect of Fe Content on the Contact Resistance of Electroplated Au-Fe Alloy Layers

H.-S. Park I. Son
Archives of Metallurgy and Materials | 2018 | vol. 63 | No 3 | 1503-1507 | DOI: 10.24425/123839
Keywords Electroplating Au-Fe alloy contact resistance Thermal aging
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Abstract

In this study, variations in the contact resistance of electroplated Au-Fe alloy layers with Fe content were investigated. The contact resistance of electroplated Au-Fe alloy layers that were subject to thermal aging at 260°C in the atmosphere, tended to increase significantly with an increase in the Fe content. Through an analysis method employing X-ray photoelectron spectroscopy (XPS/ ESCA) and Auger electron spectroscopy (AES), Ni oxides, such as NiO and Ni2O3, on the surface of the thermally aged electroplated Au-Fe alloy layers were observed. It is believed that the Ni oxide existing on the surface diffused from the underlying electroplated Ni layers to the surface through the grain boundaries in the electroplated Au-Fe layers during the thermal aging. As the Fe content in the electroplated Au-Fe layers increased, the grain size decreased. As the grain size decreases, more Ni oxide was detected on the surface. Therefore, with a rise in the Fe content, more Ni diffuses to the surface via grain boundaries, and more Ni oxide is formed on the surface of the electroplated Au-Fe layers, increasing the contact resistance of the electroplated Au-Fe alloy layers.

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Authors and Affiliations

H.-S. Park
I. Son

Sn-Pd-Ni Electroplating on Bi2Te3-Based Thermoelectric Elements for Direct Thermocompression Bonding and Creation of a Reliable Bonding Interface

Seok Jun Kang Sung Hwa Bae Injoon Son
Archives of Metallurgy and Materials | 2021 | vol. 66 | No 4 | 963-966 | DOI: 10.24425/amm.2021.136406
Keywords Tin Electroplating Thermoelectric Module Thermocompression Bonding Bi2Te3 Direct Bonding
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Abstract

The Sn-Ag-Cu-based solder paste screen-printing method has primarily been used to fabricate Bi2Te3-based thermoelectric (TE) modules, as Sn-based solder alloys have a low melting temperature (approximately 220℃) and good wettability with Cu electrodes. However, this process may result in uneven solder thickness when the printing pressure is not constant. Therefore, we suggested a novel direct-bonding method between the Bi2Te3-based TE elements and the Cu electrode by electroplating a 100 µm Sn/ 1.3 µm Pd/ 3.5 µm Ni bonding layer onto the Bi2Te3-based TE elements. It was determined that there is a problem with the amount of precipitation and composition depending on the pH change, and that the results may vary depending on the composition of Pd. Thus, double plating layers were formed, Ni/Pd, which were widely commercialized. The Sn/Pd/Ni electroplating was highly reliable, resulting in a bonding strength of 8 MPa between the thermoelectric and Cu electrode components, while the Pd and Ni electroplated layer acted as a diffusion barrier between the Sn layer and the Bi2Te3 TE. This process of electroplating Sn/Pd/Ni onto the Bi2Te3 TE elements presents a novel method for the fabrication of TE modules without using the conventional Sn-alloy-paste screen-printing method.
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Authors and Affiliations

Seok Jun Kang
1
ORCID: ORCID
Sung Hwa Bae
2
ORCID: ORCID
Injoon Son
1
ORCID: ORCID
  1. Kyungpook National University, Department of Materials Science and Metallurgical Engineering, Daegu, Republic of Korea
  2. Kyushu University, Graduate School of Engineering, Department of Materials Process Engineering, Fukuoka, Japan

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