• Title/Summary/Keyword: Electroless-Ni

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DMAB Effects in Electroless Ni Plating for Flexible Printed Circuit Board (DMAB첨가량에 따른 연성회로기판을 위한 무전해 Ni 도금박막에 관한 연구)

  • Kim, Hyung-Chul;Rha, Sa-Kyun;Lee, Youn-Seoung
    • Korean Journal of Materials Research
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    • v.24 no.11
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    • pp.632-638
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    • 2014
  • We investigated the effects of DMAB (Borane dimethylamine complex, C2H10BN) in electroless Ni-B film with addition of DMAB as reducing agent for electroless Ni plating. The electroless Ni-B films were formed by electroless plating of near neutral pH (pH 6.5 and pH 7) at $50^{\circ}C$. The electroless plated Ni-B films were coated on screen printed Ag pattern/PET (polyethylene terephthalate). According to the increase of DMAB (from 0 to 1 mole), the deposition rate and the grain size of electroless Ni-B film increased and the boron (B) content also increased. In crystallinity of electroless Ni-B films, an amorphization reaction was enhanced in the formation of Ni-B film with an increasing content of DMAB; the Ni-B film with < 1 B at.% had a weak fcc structure with a nano crystalline size, and the Ni-B films with > 5 B at.% had an amorphous structure. In addition, the Ni-B film was selectively grown on the printed Ag paste layer without damage to the PET surface. From this result, we concluded that formation of electroless Ni-B film is possible by a neutral process (~green process) at a low temperature of $50^{\circ}C$.

Comparison of Deposition Behavior and Properties of Cyanide-free Electroless Au Plating on Various Underlayer Electroless Ni-P films

  • Kim, Dong-Huyn
    • Journal of Surface Science and Engineering
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    • v.55 no.4
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    • pp.202-214
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    • 2022
  • Internal connections between device, package and external terminals for connecting packaging and printed circuit board are normally manufactured by electroless Ni-P plating followed by immersion Au plating (ENIG process) to ensure the connection reliability. In this study, a new non-cyanide-based immersion and electroless Au plating solutions using thiomalic acid as a complexing agent and aminoethanethiol as a reducing agent was investigated on different underlayer electroless Ni-P plating layers. As a result, it was confirmed that the deposition behavior and film properties of electroless Au plating are affected by grain size and impurity of the electroless Ni-P film, which is used as the plating underlayer. Au plating on the electroless Ni-P plating film with a dense surface structure showed the highest bonding strength. In addition, the electroless Au plating film on the Ni-P plating film has a smaller particle size exhibited higher bonding strength than that on the large particle size.

Electroless Deposition on Carbide Powders (Carbide분말상의 무전해 도금)

  • 이창언;최순돈
    • Journal of Surface Science and Engineering
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    • v.28 no.1
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    • pp.3-13
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    • 1995
  • Electroless Ni and Cu platings were conducted on $B_4C$ and SiC. In the electroless Ni plating, the deposition rate on $B_4C$ was higher than on SiC. However, the electroless Cu deposition occured with high deposition rate regardless of the carbide substrates used in this study. Uniformity of the deposits was better in the electroless Cu deposition than in the electroless Ni deposition. In the topographies of the electroless depositions, Ni deposits have grown as colony, whereas Cu deposits have grown as fine individual grains.

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Effect of Dispersion Method on Formation of Electroless Ni-CNT Coatings (분산법이 무전해 Ni-CNT 복합도금막 형성에 미치는 영향)

  • Bae, KyooSik
    • Journal of the Semiconductor & Display Technology
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    • v.13 no.3
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    • pp.51-55
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    • 2014
  • Ni-CNT(Carbon Nanotubes) composite coating is often used for the surface treatment of mechanical/electronic devices to improve the properties of the Ni coating. For the Ni-CNT coating, the dispersion of CNT fibers is a critical process. In this study, ultrasonic treatment instead of the conventional ball milling was attempted as a dispersion method for the electroless Ni-CNT coating. SEM-EDX analysis was performed and contact angle, sheet resistance, and micro-hardness were measured. Results showed that the ultrasonic treatment was comparable to the ball milling, as a dispersion method, but the difference was negligible. However, combined ball milling and ultrasonic treatment(double treatment) showed much improved micro-hardness value, above 350Hv(close to the value obtained by the Ni-CNT electroplating). In addition, electroless Ni-CNT(double-treated) coatings formed on the thin Ni film deposited by the electroless plating(double coating) showed better mechanical properties. Thus, double treatment and double coating are suggested as an improved electroless Ni-CNT coating method.

Effects of pH and Plating Bath Temperature on Formation of Eco-Friendly Electroless Ni-P Plating Film on Aluminum (알루미늄 위 친환경적 무전해 Ni-P 도금막 형성에 pH와 도금조 온도가 미치는 영향)

  • Gee, Hyun-Bae;Bin, Jung-Su;Lee, Youn-Seoung;Rha, Sa-Kyun
    • Korean Journal of Materials Research
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    • v.32 no.9
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    • pp.361-368
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    • 2022
  • The overall process, from the pre-treatment of aluminum substrates to the eco-friendly neutral electroless Ni-P plating process, was observed, compared, and analysed. To remove the surface oxide layer on the aluminum substrate and aid Ni-P plating, a zincation process was carried out. After the second zincation treatment, it was confirmed that a mostly uniform Zn layer was formed and the surface oxide of aluminum was also removed. The Ni-P electroless plating films were formed on the secondary zincated aluminum substrate using electroless plating solutions of pH 4.5 and neutral pH 7.0, respectively, while changing the plating bath temperature. When a neutral pH7.0 electroless solution was used, the Ni-P plating layer was uniformly formed even at the plating bath temperature of 50 ℃, and the plating speed was remarkably increased as the bath temperature was increased. On the other hand, when a pH 4.5 Ni-P electroless solution was used, a Ni-P plating film was not formed at a plating bath temperature of 50 ℃, and the plating speed was very slow compared to pH 7.0, although plating speed increased with increasing bath temperature. In the P contents, the P concentration of the neutral pH 7.0 Ni-P electroless plating layer was reduced by ~ 42.3 % compared to pH 4.5. Structurally, all of the Ni-P electroless plating layers formed in the pH 4.5 solution and the neutral (pH 7.0) solution had an amorphous crystal structure, as a Ni-P compound, regardless of the plating bath temperature.

Electroless Ni Plating on Pb-base Ceramics (Pb계 Ceramics 기지상의 무전해 Ni 도금)

  • 민봉기;유종수;최순돈;신현준
    • Journal of Surface Science and Engineering
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    • v.32 no.4
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    • pp.487-495
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    • 1999
  • In order to form metallic electrodes on PZT (Pb (Zr, Ti)O$_3$) ceramics, plating conditions for optimal electroless Ni deposition were investigated. Pb in PZT is the major component to inhibit the electroless deposition, because it plays a active role of catalytic poison in plating solution. Adhesion of the electroless Ni deposits is measured by push-pull scale test and peel test. Results such as deposition ability, deposition rate, and thickness of deposits showed in terms of concentration of etchant, composition of catalyzing solution, and composition and pH of electroless bath solution.

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Fabrication of the Diffusion Barrier for Bus Electrode of Plasma Display by Electroless Ni-B Plating (무전해 Ni-B 도금을 이용한 플라즈마 디스플레이 버스 전극의 확산 방지막 제조)

  • Choi, Jae-Woong;Hong, Seok-Jun;Lee, Hee-Yeol;Kang, Sung-Goon
    • Korean Journal of Materials Research
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    • v.13 no.2
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    • pp.101-105
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    • 2003
  • In this study, we have investigated the availability of the electroless Ni-B plating for a diffusion barrier of the bus electrode. The Ni-B layer of 1$\beta$: thick was electroless deposited on the electroplated Cu bus electrode for AC plasma display. The layer was to encapsulate Cu bus electrode to prevent from its oxidation and to serve as a diffusion barrier against Cu contamination of the transparent dielectric layer in AC plasma display. The microstructure of the as-plated barrier layer was made of an amorphous phase and the structure was converted to crystalline at about 30$0^{\circ}C$. The concentration of boron was about 5∼6 wt.% in the electroless Ni-B deposit regardless of DMAB concentration. The electroless Ni-B deposit was coated on the surface of the electroplated Cu bus electrode uniformly. And the electroless Ni-B plating was found to be an appropriate process to form the diffusion barrier.

Effect of underlayer electroless Ni-P plating on deposition behavior of cyanide-free electroless Au plating (비시안 무전해 Au 도금의 석출거동에 미치는 하지층 무전해 Ni-P 도금 조건의 영향)

  • Kim, DongHyun;Han, Jaeho
    • Journal of Surface Science and Engineering
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    • v.55 no.5
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    • pp.299-307
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    • 2022
  • Gold plating is used as a coating of connector in printed circuit boards, ceramic integrated circuit packages, semiconductor devices and so on, because the film has excellent electric conductivity, solderability and chemical properties such as durability to acid and other chemicals. In most cases, internal connection between device and package and external terminals for connecting packaging and printed circuit board are electroless Ni-P plating followed by immersion Au plating (ENIG) to ensure connection reliability. The deposition behavior and film properties of electroless Au plating are affected by P content, grain size and mixed impurity components in the electroless Ni-P alloy film used as the underlayer plating. In this study, the correlation between electroless nickel plating used as a underlayer layer and cyanide-free electroless Au plating using thiomalic acid as a complexing agent and aminoethanethiol as a reducing agent was investigated.

A Study of the fracture of intermetallic layer in electroless Ni/Au plating (무전해 니켈/금도금에서의 내부 금속층의 결함에 대한 연구)

  • 박수길;정승준;김재용;엄명헌;엄재석;전세호
    • Proceedings of the Korean Institute of Electrical and Electronic Material Engineers Conference
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    • 1999.05a
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    • pp.708-711
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    • 1999
  • The Cu/Ni/Au lamellar structure is extensively used as an under bump metallization on silicon file, and on printed circuit board(PCB) pads. Ni is plated Cu by either electroless Ni plating, or electrolytic Ni plating. Unlike the electrolytic Ni plating, the electroless Ni plating does not deposit pure Ni, but a mixture of Ni and phosphorous, because hypophosphite Is used in the chemical reaction for reducing Ni ions. The fracture crack extended at the interface between solder balls of plastic ball grid (PBGA) package and conducting pads of PCB. The fracture is duets to segregation at the interface between Ni$_3$Sn$_4$intermetallic and Ni-P layer. The XPS diffraction results of Cu/Ni/Au results of CU/Ni/AU finishs showed that the Ni was amorphous with supersaturated P. The XPS and EDXA results of the fracture surface indicated that both of the fracture occurred on the transition lesion where Sn, P and Ni concentrations changed.

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Study on Electroless Black Ni-Zn Plating Using Hydrazine as a Reducing Agent (히드라진에 의한 무전해 흑색 니켈-아연 합금 도금에 대한 연구)

  • 오영주;정원용;이만승
    • Journal of Surface Science and Engineering
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    • v.36 no.5
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    • pp.393-397
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    • 2003
  • The effects of the composition and additives on the blackening and deposition rate of electroless Ni-Zn plating have been examined. Hydrazine resulted in lower sheet resistance of the deposit than sodium hypophosphite. Zinc concentration more than 15 wt% and small amount of ammonium sulfate in the deposits were needed in obtaining Ni-Zn deposit with a black color. An optimum condition was obtained for the black Ni-Zn deposit at an appreciable deposition rate.