AI Article Synopsis
- High-density integration of components for mobile communication is essential due to the demand for compact, lightweight devices, necessitating the embedding of passive components in multi-layer ceramic chips.
- Efforts to combine different low-temperature co-fired ceramics (LTCC) have faced challenges like de-laminations and internal cracks, primarily due to varying thermal expansion coefficients, suggesting that using a common glass may help mitigate these issues.
- In this study, Ca-Al-Si-O glass was mixed with different LTCC fillers, achieving varying dielectric constants; notably, a mixture with 1.3MgO-TiO achieved a dielectric constant of 7.9 and a quality factor of 3708, while cordierite yielded a dielectric constant of 5 and a
Article Abstract
High-density integration in single component used for mobile communication is highly demanded with the miniaturization trend in multi-functional light-weighted mobile communication devices. Embedding passive components into multi-layered ceramic chips is also increasingly needed for high integrity. The need for high strength materials to be used in handheld devices has also increased. To this end, many attempts to join different low-temperature co-fired ceramics (LTCC) materials with different dielectric constants have been made, but failed with de-laminations or internal cracks mainly due to difference of thermal expansion coefficients. It is thought that this difference could be minimized with the use of common glass in different LTCC materials. In this study, several candidates of common glass were mixed with various fillers of LTCC to have various dielectric constants in the radio-frequency, and to minimize the mismatch in joining. Ca-Al-Si-O glass was mixed with 1.3MgO-TiO, cordierite and CaTiO. Mixtures were tape-cast and sintered to be compared with their micro-structures, dielectric properties and thermo-mechanical characteristics. When 1.3MgO-TiO with volumetric ratio of 30% was mixed with Ca-Al-Si-O glass, the measured dielectric constant was 7.9, the quality factor was 3708. With 45 volumetric percent of cordierite, the dielectric constant was 5 and the quality factor was 1052.
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|---|---|
| http://www.ncbi.nlm.nih.gov/pmc/articles/PMC4433905 | PMC |
| http://dx.doi.org/10.1080/13102818.2014.949039 | DOI Listing |
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