• Title/Summary/Keyword: LTCC green sheets

Search Result 15, Processing Time 0.028 seconds

Effect of Solvent Mixture on the Properties of LTCC Slurry and Green Sheets (LTCC 슬러리 및 그린시트의 물성 변화에 미치는 혼합용매 조성의 영향)

  • Cho, Beom-Joon;Park, Eun-Tae
    • Korean Journal of Materials Research
    • /
    • v.16 no.9
    • /
    • pp.533-537
    • /
    • 2006
  • The effects of binary solvent mixtures with various ratios of toluene and ethanol on the properties of slurries and green sheets were investigated. Viscosity of slurry was changed by varying the ratio of solvent mixture which affected the solubility of binder. The relative solvency behavior of a solvent mixture could be predicted with the Hildebrand solubility parameter(${\delta}$) and hydrogen bonding index( ${\gamma}$). The minimum viscosity, the best dispersion of binder, was reached at the composition of toluene:ethanol=4:6, which corresponded to our forecast. The mechanical properties of green sheets related to evaporation of solvents were influenced by the composition of the solvent mixture. At the azeotrope the skin was formed on a drying cast during the drying process because of fast evaporation. At a range of concentrations over 50wt% toluene, green sheets could not be fully dried at low temperature due to excessive toluene. The mechanical properties of green sheets were excellent at the azeotrope-like composition of toluene:ethanol=4:6 which has a little excess of toluene over the azeotrope.

Control of Explosion Behavior in Micro Hole Using UV Laser on LTCC Green Sheets Containing Carbon Particles (카본을 첨가한 LTCC 그린 시트에서 UV 레이저를 이용한 미세 홀 터짐 현상 제어)

  • Kim, Shi Yeon;Ahn, Ik-Joon;Yeo, Dong-Hun;Shin, Hyo-Soon;Yoon, Ho Gyu
    • Journal of the Korean Institute of Electrical and Electronic Material Engineers
    • /
    • v.29 no.12
    • /
    • pp.786-790
    • /
    • 2016
  • Hole explosion behaviors were observed during drilling fine holes with laser beam on the LTCC green bar of $320{\mu}m$ thick after lamination of green sheets prepared by tape casting of thick film process. The incidence of these hole explosions was inversely proportional to hole sizes. The incidence of hole explosion was 20 % number of hole with the size of $60{\mu}m$ exploded for the UV radiation, while the explosion did not appear for hole sizes over $100{\mu}m$. To prevent hole explosion behavior during laser-drilling of fine holes, carbon black powder was added as an additive in the LTCC composition, which has superior thermal durability. As a consequence, hole explosion rate was suppressed to 0.8 % for the hole size of $50{\mu}m$ green sheet with the carbon black amount of 10 weight % and the laser power of 3 watt. Added carbon is thought to reduce the heat-affected region during laser drilling.

Suppression of Shrinkage Mismatch in Hetero-Laminates Between Different Functional LTCC Materials

  • Seung Kyu Jeon;Zeehoon Park;Hyo-Soon Shin;Dong-Hun Yeo;Sahn Nahm
    • Journal of the Korean Institute of Electrical and Electronic Material Engineers
    • /
    • v.36 no.2
    • /
    • pp.151-157
    • /
    • 2023
  • Integrating dielectric materials into LTCC is a convenient method to increase the integration density in electronic circuits. To enable co-firing of the high-k and low-k dielectric LTCC materials in a multi-material hetero-laminate, the shrinkage characteristics of both materials should be similar. Moreover, thermal expansion mismatch between materials during co-firing should be minimized. The alternating stacking of an LTCC with silica filler and that with calcium-zirconate filler was observed to examine the use of the same glass in different LTCCs to minimize the difference in shrinkage and thermal expansion coefficient. For the LTCC of silica filler with a low dielectric constant and that of calcium zirconate filler with a high dielectric constant, the amount of shrinkage was examined through a thermomechanical analysis, and the predicted appropriate fraction of each filler was applied to green sheets by tape casting. The green sheets of different fillers were alternatingly laminated to the thickness of 500 ㎛. As a result of examining the junction, it was observed through SEM that a complete bonding was achieved by constrained sintering in the structure of 'calcium zirconate 50 vol%-silica 30 vol%-calcium zirconate 50 vol%'.

Effect of Binder Content on Physical Properties of LTCC Green Tapes (바인더 함량 변화가 LTCC 그린 테이프의 물리적 특성에 미치는 영향)

  • You, Jung-Hoon;Yeo, Dong-Hun;Lee, Joo-Sung;Shin, Hyo-Soon;Yoon, Ho-Gyu;Kim, Jong-Hee
    • Journal of the Korean Institute of Electrical and Electronic Material Engineers
    • /
    • v.19 no.12
    • /
    • pp.1112-1117
    • /
    • 2006
  • The properties of LTCC green tape with addition of binder were investigated in order to understand an effects of binder on multilayer processing. A green sheet form was fabricated through tape casting method with the MLS-22 powder. The lamination density increased with increasing amount of binder and lamination pressure. With increasing amount of binder, the elongation of ceramic sheets increased but the tensile stress and air-permeability decreased. The addition of excessive binder is caused defects in the green sheet during via hole punching. The optimum condition of the via hole without defects was observed from amount of the binder 10 wt%.

Warpage of Co-fired High K/Low K LTCC Substrate (고유전율/저유전율 LTCC 동시소성 기판의 휨 현상)

  • Cho, Hyun-Min;Kim, Hyeong-Joon;Lee, Chung-Seok;Bang, Kyu-Seok;Kang, Nam-Kee
    • Journal of the Microelectronics and Packaging Society
    • /
    • v.11 no.3 s.32
    • /
    • pp.77-82
    • /
    • 2004
  • In this paper, warpages of heterogeneous LTCC substrates comprised of high K/low K hi-layered structure were investigated. The effect of glass content in high K LTCC layer on the warpage of substrate during co-firing process was examined. Shrinkage and dielectric properties of high K and low K green sheets were measured. In-situ camber observation by hot stage microscopy showed different camber development of heterogeneous LTCC substrates according to glass content in high K green sheet. High K green sheet containing $50\%$ glass was matched to low K green sheet in the shrinkage. Therefore, LTCC substrate of Low K/High K+$50\%$ glass structure showed flat surface after sintering.

  • PDF

Physical Properties of Green Sheets According to Glass Transition Temperature of Binder (바인더 유리전이온도에 따른 그린시트의 물리적 특성)

  • Kwon, Hyeok-Jung;Yeo, Dong-Hun;Shin, Hyo-Soon
    • Journal of the Korean Institute of Electrical and Electronic Material Engineers
    • /
    • v.26 no.1
    • /
    • pp.33-37
    • /
    • 2013
  • The properties of LTCC green sheets formed by the MLS-22 powder of NEG Inc. were investigated for acrylic binders with different PVB and Tg in the variation of temperature. The elongation of the green sheets showed large variation depending on the temperature, and was rapidly decreased near the Tg of the sheets. With the increase of the ratio of plasticizer/binder (P/B), large elongation of the sheets was observed due to the decrease of the Tg. In the stacking process of the multilayer ceramic, the optimal control of the temperature is highly required depending on the Tg of the binder and the ratio of P/Buniform coating.

Development of Green-Sheet Measurement Algorithm by Image Processing Technique (영상처리기법을 이용한 그린시트 측정알고리즘 개발)

  • Pyo, C.R.;Yang, S.M.;Kang, S.H.;Yoon, S.M.
    • Transactions of Materials Processing
    • /
    • v.16 no.4 s.94
    • /
    • pp.313-316
    • /
    • 2007
  • The purpose of this paper is the development of measurement algorithm for green-sheet based on the digital image processing technique. The Low Temperature Co-fired Ceramic(LTCC) technology can be employed to produce multilayer circuits with the help of single tapes, which are used to apply conductive, dielectric and/or resistive pastes on. These single green-sheets must be laminated together and fired at the same time. Main function of the green-sheet film measurement algorithm is to measure the position and size of the punching hole in each single layer. The line scan camera coupled with motorized X-Y stage is used. In order to measure the entire film area using several scanning steps, an overlapping method is used.

LTCC and LTCC-M Technologies for Multichip Module (Multichip module 개발을 위한 LTCC 밀 LTCC-M 기술)

  • 박성대;강현규;박윤휘;문제도
    • Journal of the Microelectronics and Packaging Society
    • /
    • v.6 no.3
    • /
    • pp.25-35
    • /
    • 1999
  • LTCC (Low Temperature Cofired Ceramic) or LTCC-M (Low Temperature Cofired ceramic on Metal) technology is one of MCM-C (Multichip Module on Ceramic) technologies and becomes to be widely used in consumer, RF and automotive electronics. As green sheets for LTCC are cofired below $1000^{\circ}C$ in comparison with those for HTCC (High Temperature Cofired Ceramic), high conductivity metal traces such as gold, silver and copper can be used. The dimensional stability in LTCC-M technology enables embedded passives to be integrated inside modules, which enhances the electrical performance and increases the reliability of the modules. Coefficient of thermal expansion and dielectric constant can be controlled by changing composition and heating profile for cofiring. In this technical review, LTCC and LTCC-M technologies are introduced and advantages of those technologies are explained.

  • PDF

Effect of Solvent Mixture Ratio on Rheology Property of Slurry and Thickness Control of Ceramic Green Sheets (유기 용매 혼합비에 따른 슬러리의 유동 특성과 세라믹 그린 쉬트의 두께 제어)

  • Kim, Jun-Young;Kim, Seung-Taek;Park, Jong-Chul;Yoo, Myong-Jae
    • Journal of the Korean Institute of Electrical and Electronic Material Engineers
    • /
    • v.21 no.3
    • /
    • pp.236-241
    • /
    • 2008
  • The effect of organic solvent mixture ratio on the rheology property of slurry and thickness control of ceramic green sheet was investigated. For selecting a suitable dispersant multiple light scattering method was used to evaluate the particle migration velocity and variation of clarification layer thickness. Using the selected dispersant the dispersion property of solution according to solvent mixture ratio was investigated. Binder and plasticizers were added to formulate slurries and their viscosity was evaluated according to solvent mixture ratio. Ceramic green sheets with average thickness of 30, 50 urn were fabricated via tape casting and their thickness tolerances measured. As a result according to solvent mixture ratio the solution and slurry properties varied and for the mixture ratio of ethanol/toluene of 80/20 the ceramic green sheet with the lowest thickness tolerance was obtained.

Microstructure and Thermal Insulation Properties of Ultra-Thin Thermal Insulating Substrate Containing 2-D Porous Layer (2차원 기공층을 포함하는 초박형 단열기판의 미세구조 및 단열 특성)

  • Yoo, Chang Min;Lee, Chang Hyun;Shin, Hyo Soon;Yeo, Dong Hun;Kim, Sung Hoon
    • Journal of the Korean Institute of Electrical and Electronic Material Engineers
    • /
    • v.30 no.11
    • /
    • pp.683-687
    • /
    • 2017
  • We investigated the structure of an ultra-thin insulating board with low thermal conductivity along z-axis, which was based on the idea of void layers created during the glass infiltration process for the zero-shrinkage low-temperature co-fired ceramic (LTCC) technology. An alumina and four glass powders were chosen and prepared as green sheets by the tape casting method. After comparison of the four glass powders, bismuth glass was selected for the experiment. Since there is no notable reactivity between alumina and bismuth glass, alumina was selected as the supporting additive in glass layers. With 2.5 vol% of alumina powder, glass green sheets were prepared and stacked alternately with alumina green sheet to form the 'alumina/glass (including alumina additive)/alumina' structure. The stacked green sheets were sintered into an insulating substrate. Scanning electron microscopy revealed that the additive alumina formed supporting bridges in void layers. The depth and number of the stacking layers were varied to examine the insulating property. The lowest thermal conductivity obtained was 0.23 W/mK with a $500-{\mu}m-thick$ substrate.