• Title/Summary/Keyword: Laser-Induced Forward Transfer

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Deposition of Fine Linewidth Silver Layer using a Modified Laser-induced Forward Transfer Technique

  • Cheon, Jonggyu;Nguyen, Manh-Cuong;Nguyen, An Hoang-Thuy;Choi, Sujin;Ji, Hyung-Min;Kim, Sang-Woo;Yu, Kyoung-Moon;Kim, Jin-Hyun;Cho, Seong-Yong;Choi, Rino
    • Journal of the Korean Physical Society
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    • v.73 no.9
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    • pp.1279-1282
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    • 2018
  • This paper reports the deposition of a metal line using a multilayer stack and laser-induced forward transfer (LIFT) using a low cost continuous wave blue laser with a wavelength of 450 nm. The donor structure was composed of a light-to-heat (LTH) layer, a release layer, and a transfer layer in series. Amorphous silicon as the LTH layer absorbs photon energy and converts it to heat. A release layer was melted so that a silver transfer layer would be transferred to the receiver substrate. The transferred silver layer showed reasonable physical and electrical characteristics. A low cost fine linewidth metal layer could be achieved using this modified LIFT technique and blue laser.

Micro patterning of conductor line by laser induced forward transfer(LIFT) (LIFT 방법에 의한 전도성 미세 패터닝 공정 연구)

  • 이제훈;한유희
    • Laser Solutions
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    • v.2 no.3
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    • pp.52-61
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    • 1999
  • The laser induced forward transfer(LIFT) technique employs a pulsed laser to transfer parts of a thin metal film from an optically transparent target onto an arbitrary substrate in close proximity to the metal film on the target. In this work, a two-step method, the combination of LIFT process, in which a Au film deposited on the $Al_2$O$_3$ substrate by Nd:YAG laser and subsequent Au electroless metal plating on the by LIFT process generated Au seed, was presented. The influence of laser parameters, wavelength, laser power, film thickness and overlap ratio of pulse tracks, on the shapes of deposit and conductor line after electroless plating is experimentally studied. As a results, the threshold power densities for ablation, deposition and metallization were determined and comparison of threshold value between the wave length 1064nm and the second harmonic generated 532nm. In odor to determine a possible application in the electronic industry, a smallest conduct spot size, line width and isolated line space were generated.

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Solder Bump Deposition Using a Laser Beam (레이저빔을 이용한 솔더범프 적층 공정)

  • Choi, Won-Suk;Kim, Jea-Woon;Kim, Jong-Hyeong;Kim, Joo-Han
    • Transactions of the Korean Society of Mechanical Engineers A
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    • v.36 no.1
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    • pp.37-42
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    • 2012
  • LIFT (laser-induced forward transfer) is an advanced laser processing method used for selectively transferring micron-sized objects. In our study, this process was applied in order to deposit solder balls in microsystem packaging processes for electronics. Locally melted solder paste could be transferred to a rigid substrate using laser pulses. A thin glass plate with a solder cream layer was used as a donor film, and an IR laser pulse (wavelength = 1070 nm) was used to transfer a micron-sized solder ball to the receptor. Mass balance and energy balance were applied to analyze the shape and temperature profiles of the solder paste drops. The transferred solder bumps had measured diameters of 30-40 ${\mu}m$ and thicknesses of 50 ${\mu}m$ in our experiment. The limits and applications of this method are also presented.

Microfabrication of Micro-Conductive patterns on Insulating Substrate by Electroless Nickel Plating (무전해 니켈 도금을 이용한 절연기판상의 미세전도성 패턴 제조)

  • Lee, Bong-Gu;Moon, Jun Hee
    • Korean Journal of Metals and Materials
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    • v.48 no.1
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    • pp.90-100
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    • 2010
  • Micro-conductive patterns were microfabricated on an insulating substrate ($SiO_2$) surface by a selective electroless nickel plating process in order to investigate the formation of seed layers. To fabricate micro-conductive patterns, a thin layer of metal (Cu.Cr) was deposited in the desired micropattern using laser-induced forward transfer (LIFT). and above this layer, a second layer was plated by selective electroless plating. The LIFT process. which was carried out in multi-scan mode, was used to fabricate micro-conductive patterns via electroless nickel plating. This method helps to improve the deposition process for forming seed patterns on the insulating substrate surface and the electrical conductivity of the resulting patterns. This study analyzes the effect of seed pattern formation by LIFT and key parameters in electroless nickel plating during micro-conductive pattern fabrication. The effects of the process variables on the cross-sectional shape and surface quality of the deposited patterns are examined using field emission scanning electron microscopy (FE-SEM) and an optical microscope.

Improvement of Conductive Micro-pattern Fabrication using a LIFT Process (레이저 직접묘화법을 이용한 미세패턴 전도성 향상에 관한 연구)

  • Lee, Bong-Gu
    • Journal of the Korea Academia-Industrial cooperation Society
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    • v.18 no.5
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    • pp.475-480
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    • 2017
  • In this paper, the conductivity of the fine pattern is improved in the insulating substrate by laser-induced forward transfer (LIFT) process. The high laser beam energy generated in conventional laser induced deposition processes induces problems such as low deposition density and oxidation of micro-patterns. These problems were improved by using a polymer coating layer for improved deposition accuracy and conductivity. Chromium and copper were used to deposit micro-patterns on silicon wafers. A multi-pulse laser beam was irradiated on a metal thin film to form a seed layer on an insulating substrate(SiO2) and electroless plating was applied on the seed layer to form a micro-pattern and structure. Irradiating the laser beam with multiple scanning method revealed that the energy of the laser beam improved the deposition density and the surface quality of the deposition layer and that the electric conductivity can be used as the microelectrode pattern. Measuring the resistivity after depositing the microelectrode by using the laser direct drawing method and electroless plating indicated that the resistivity of the microelectrode pattern was $6.4{\Omega}$, the resistance after plating was $2.6{\Omega}$, and the surface texture of the microelectrode pattern was uniformly deposited. Because the surface texture was uniform and densely deposited, the electrical conductivity was improved about three fold.