• Title/Summary/Keyword: pulse-reverse plating

Search Result 11, Processing Time 0.02 seconds

$CH_4N_2S$$C_{10}H_{13}NO_3S$ 첨가가 Ni 패턴 상의 구리도금 형상에 미치는 영향

  • Lee, Jin-Hyeong;Lee, Ju-Yeol;Kim, Man
    • Proceedings of the Korean Institute of Surface Engineering Conference
    • /
    • 2009.10a
    • /
    • pp.155-155
    • /
    • 2009
  • The copper plating was deposited by pulse reverse current (PRC) method with additives. The all specimens were first immersted in 10% H2SO4 for 10 minutes, and then were rinsed with deionized water. The current densities of forward pulse were 400mA/$cm^2$, and those of reverse pulse were 1900mA/$cm^2$ and 100mA/$cm^2$. Results are compared for different additives for pulse plating conditions. When it added in Only CH4N2S (TU) or only C10H13NO3S (SVH), the effect of surface side growth of Cu was not different. But when it added in TU and SVH, surface side growth of Cu decreased. Polarization curves were measured from OCP to -0.7 V at a rate of 1mV/sec. Each specimen was observed under the PHENOM to see surface morphology.

  • PDF

Characteristics of Plated Bump on Multi-layer Build up PCB by Pulse-reverse Electroplating (Pulse-reverse도금을 이용한 다층 PCB 빌드업 기판용 범프 생성특성)

  • Seo, Min-Hye;Kong, Man-Sik;Hong, Hyun-Seon;Sun, Jee-Wan;Kong, Ki-Oh;Kang, Kae-Myung
    • Korean Journal of Materials Research
    • /
    • v.19 no.3
    • /
    • pp.151-155
    • /
    • 2009
  • Micro-scale copper bumps for build-up PCB were electroplated using a pulse-reverse method. The effects of the current density, pulse-reverse ratio and brightener concentration of the electroplating process were investigated and optimized for suitable performance. The electroplated micro-bumps were characterized using various analytical tools, including an optical microscope, a scanning electron microscope and an atomic force microscope. Surface analysis results showed that the electroplating uniformity was viable in a current density range of 1.4-3.0 A/$dm^2$ at a pulse-reverse ratio of 1. To investigate the brightener concentration on the electroplating properties, the current density value was fixed at 3.0 A/$dm^2$ as a dense microstructure was achieved at this current density. The brightener concentration was varied from 0.05 to 0.3 ml/L to study the effect of the concentration. The optimum concentration for micro-bump electroplating was found to be 0.05 ml/L based on the examination of the electroplating properties of the bump shape, roughness and grain size.

The Effects of Electroplating Parameters on the Morphologies and Compositions of Nickel-Iron Alloy Electrodeposits (Ni-Fe의 도금 층의 조성과 표면 형상에 영향을 미치는 도금인자들에 관한 연구)

  • Ko, Yeong-Kwon;Yim, Tai-Hong;Lee, Jae-Ho
    • Journal of the Microelectronics and Packaging Society
    • /
    • v.14 no.3
    • /
    • pp.51-55
    • /
    • 2007
  • Nickel iron (Ni-Fe) alloy coating was investigated. The effects of the current density, current type, pulse duration and bath compositions on the morphologies and surface hardness of nickeliron deposits as well as the chemical compositions were investigated. The morphologies, surface hardness and chemical compositions of nickel-iron deposits were varied with current density, current type and bath compositions. The surface hardness was increased up to $550{\sim}600Hv$ when PC plating was employed. Crackless coating was obtained when saccharin was added. The change of composition with thickness was analyzed with EDS and FESEM.

  • PDF

Electroplating of Copper Using Pulse-Reverse Electroplating Method for SiP Via Filling (펄스-역펄스 전착법을 이용한 SiP용 via의 구리 충진에 관한 연구)

  • Bae J. S.;Chang G H.;Lee J. H.
    • Journal of the Microelectronics and Packaging Society
    • /
    • v.12 no.2 s.35
    • /
    • pp.129-134
    • /
    • 2005
  • Electroplating copper is the important role in formation of 3D stacking interconnection in SiP (System in Package). The I-V characteristics curves are investigated at different electrolyte conditions. Inhibitor and accelerator are used simultaneously to investigate the effects of additives. Three different sizes of via are tested. All via were prepared with RIE (reactive ion etching) method. Via's diameter are 50, 75, $100{\mu}m$ and the height is $100{\mu}m$. Inside via, Ta was deposited for diffusion barrier and Cu was deposited fer seed layer using magnetron sputtering method. DC, pulse and pulse revere current are used in this study. With DC, via cannot be filled without defects. Pulse plating can improve the filling patterns however it cannot completely filled copper without defects. Via was filled completely without defects using pulse-reverse electroplating method.

  • PDF

High Speed Cu Filling into Tapered TSV for 3-dimensional Si Chip Stacking (3차원 Si칩 실장을 위한 경사벽 TSV의 Cu 고속 충전)

  • Kim, In Rak;Hong, Sung Chul;Jung, Jae Pil
    • Korean Journal of Metals and Materials
    • /
    • v.49 no.5
    • /
    • pp.388-394
    • /
    • 2011
  • High speed copper filling into TSV (through-silicon-via) for three dimensional stacking of Si chips was investigated. For this study, a tapered via was prepared on a Si wafer by the DRIE (deep reactive ion etching) process. The via had a diameter of 37${\mu}m$ at the via opening, and 32${\mu}m$ at the via bottom, respectively and a depth of 70${\mu}m$. $SiO_2$, Ti, and Au layers were coated as functional layers on the via wall. In order to increase the filling ratio of Cu into the via, a PPR (periodic pulse reverse) wave current was applied to the Si chip during electroplating, and a PR (pulse reverse) wave current was applied for comparison. After Cu filling, the cross sections of the vias was observed by FE-SEM (field emission scanning electron microscopy). The experimental results show that the tapered via was filled to 100% at -5.85 mA/$cm^2$ for 60 min of plating by PPR wave current. The filling ratio into the tapered via by the PPR current was 2.5 times higher than that of a straight via by PR current. The tapered via by the PPR electroplating process was confirmed to be effective to fill the TSV in a short time.

TSV Filling Technology using Cu Electrodeposition (Cu 전해도금을 이용한 TSV 충전 기술)

  • Kee, Se-Ho;Shin, Ji-Oh;Jung, Il-Ho;Kim, Won-Joong;Jung, Jae-Pil
    • Journal of Welding and Joining
    • /
    • v.32 no.3
    • /
    • pp.11-18
    • /
    • 2014
  • TSV(through silicon via) filling technology is making a hole in Si wafer and electrically connecting technique between front and back of Si die by filling with conductive metal. This technology allows that a three-dimensionally connected Si die can make without a large number of wire-bonding. These TSV technologies require various engineering skills such as forming a via hole, forming a functional thin film, filling a conductive metal, polishing a wafer, chip stacking and TSV reliability analysis. This paper addresses the TSV filling using Cu electrodeposition. The impact of plating conditions with additives and current density on electrodeposition will be considered. There are additives such as accelerator, inhibitor, leveler, etc. suitably controlling the amount of the additive is important. Also, in order to fill conductive material in whole TSV hole, current wave forms such as PR(pulse reverse), PPR(periodic pulse reverse) are used. This study about semiconductor packaging will be able to contribute to the commercialization of 3D TSV technology.

Effects of Electroplating Condition on Micro Bump of Multi-Layer Build-Up PCB (다층 PCB 빌드업 기판용 마이크로 범프 도금에 미치는 전해조건의 영향)

  • Seo, Min-Hye;Hong, Hyun-Seon;Jung, Woon-Suk
    • Korean Journal of Materials Research
    • /
    • v.18 no.3
    • /
    • pp.117-122
    • /
    • 2008
  • Micro-sized bumps on a multi-layered build-up PCB were fabricated by pulse-reverse copper electroplating. The values of the current density and brightener content for the electroplating were optimized for suitable performance with maximum efficiency. The micro-bumps thus electroplated were characterized using a range of analytical tools that included an optical microscope, a scanning electron microscope, an atomic force microscope and a hydraulic bulge tester. The optical microscope and scanning electron microscope analyses results showed that the uniformity of the electroplating was viable in the current density range of $2-4\;A/dm^2$; however, the uniformity was slightly degraded as the current density increased. To study the effect of the brightener concentration, the concentration was varied from zero to 1.2 ml/L. The optimum concentration for micro-bump electroplating was found to be 0.6 ml/L based on an examination of the electroplating properties, including the roughness, yield strength and grain size.

High Speed Cu Filling Into TSV by Pulsed Current for 3 Dimensional Chip Stacking (3차원 실장용 TSV의 펄스전류 파형을 이용한 고속 Cu도금 충전)

  • Kim, In Rak;Park, Jun Kyu;Chu, Yong Cheol;Jung, Jae Pil
    • Korean Journal of Metals and Materials
    • /
    • v.48 no.7
    • /
    • pp.667-673
    • /
    • 2010
  • Copper filling into TSV (through-silicon-via) and reduction of the filling time for the three dimensional chip stacking were investigated in this study. A Si wafer with straight vias - $30\;{\mu}m$ in diameter and $60\;{\mu}m$ in depth with $200\;{\mu}m$ pitch - where the vias were drilled by DRIE (Deep Reactive Ion Etching) process, was prepared as a substrate. $SiO_2$, Ti and Au layers were coated as functional layers on the via wall. In order to reduce the time required complete the Cu filling into the TSV, the PPR (periodic pulse reverse) wave current was applied to the cathode of a Si chip during electroplating, and the PR (pulse-reverse) wave current was also applied for a comparison. The experimental results showed 100% filling rate into the TSV in one hour was achieved by the PPR electroplating process. At the interface between the Cu filling and Ti/ Au functional layers, no defect, such as a void, was found. Meanwhile, the electroplating by the PR current showed maximum 43% filling ratio into the TSV in an hour. The applied PPR wave form was confirmed to be effective to fill the TSV in a short time.

Copper Via Filling Using Organic Additives and Wave Current Electroplating (유기물 첨가제와 펄스-역펄스 전착법을 이용한 구리 Via Filling에 관한 연구)

  • Lee, Suk-Ei;Lee, Jae-Ho
    • Journal of the Microelectronics and Packaging Society
    • /
    • v.14 no.3
    • /
    • pp.37-42
    • /
    • 2007
  • Copper deposition studies have been actively studied since interests on 3D SiP were increased. The defects inside via can be easily formed due to the current density differences on entrance, bottom and wall of via. So far many different additives and current types were discussed and optimized to obtain void-free copper via filling. In this research acid cupric sulfate plating bath containing additives such as PEG, SPS, JGB, PEI and wave current applied electroplating were examined. The size and shape of grain were influenced by the types of organic additives. The cross section of specimen were analyzed by FESEM. When PEI was added, the denser copper deposits were obtained. Electroplaing time was reduced when 2 step via filling was employed.

  • PDF

Effective Cu Filling Method to TSV for 3-dimensional Si Chip Stacking (3차원 Si칩 실장을 위한 효과적인 Cu 충전 방법)

  • Hong, Sung Chul;Jung, Do Hyun;Jung, Jae Pil;Kim, Wonjoong
    • Korean Journal of Metals and Materials
    • /
    • v.50 no.2
    • /
    • pp.152-158
    • /
    • 2012
  • The effect of current waveform on Cu filling into TSV (through-silicon via) and the bottom-up ratio of Cu were investigated for three dimensional (3D) Si chip stacking. The TSV was prepared on an Si wafer by DRIE (deep reactive ion etching); and its diameter and depth were 30 and $60{\mu}m$, respectively. $SiO_2$, Ti and Au layers were coated as functional layers on the via wall. The current waveform was varied like a pulse, PPR (periodic pulse reverse) and 3-step PPR. As experimental results, the bottom-up ratio by the pulsed current decreased with increasing current density, and showed a value of 0.38 on average. The bottom-up ratio by the PPR current showed a value of 1.4 at a current density of $-5.85mA/cm^2$, and a value of 0.91 on average. The bottom-up ratio by the 3-step PPR current increased from 1.73 to 5.88 with time. The Cu filling by the 3-step PPR demonstrated a typical bottom-up filling, and gave a sound filling in a short time.