초록 ▼

The present invention relates to a Cd-free and Pb-free glass composition comprising, based in mol %, 1-10% MO where M is selected from Ba, Sr, Ca and mixtures thereof, 5-30% MgO, 0.3-5% CuO, 0-2. 5% P2O5, 0-2.5% ZrO2, 24-45% ZnO, 2-10% Al 2O3, 35-50% SiO2 and 0.1-3% A2O where A is selected from the

The present invention relates to a Cd-free and Pb-free glass composition comprising, based in mol %, 1-10% MO where M is selected from Ba, Sr, Ca and mixtures thereof, 5-30% MgO, 0.3-5% CuO, 0-2. 5% P2O5, 0-2.5% ZrO2, 24-45% ZnO, 2-10% Al 2O3, 35-50% SiO2 and 0.1-3% A2O where A is selected from the group of alkali elements and mixtures thereof wherein the glass composition is useful in thick paste dielectric materials which are compatible with AlN substrates.

대표청구항 ▼

What is claimed is: 1. A method of forming a multilayer circuit comprising the steps: (a) providing an aluminum nitride substrate; (b) depositing on said substrate, a Pb-free and Cd-free glass composition comprising a dispersion of finely divided solids comprising: (i) a glass composition comprisin

What is claimed is: 1. A method of forming a multilayer circuit comprising the steps: (a) providing an aluminum nitride substrate; (b) depositing on said substrate, a Pb-free and Cd-free glass composition comprising a dispersion of finely divided solids comprising: (i) a glass composition comprising, in mol %, 1-10% MO where M is selected from Ba, Sr, Ca and mixtures thereof, 5-30% MgO, 0.3-5% CuO, 0-2.5% P2O5, 0-2.5% ZrO2, 24-45% ZnO, 2-10% Al2O3, 35-50% SiO2 and 0.1-3% A2O where A is one or more alkali elements, and (ii) an organic medium; (c) firing said composition and substrate forming an aluminum nitride article; (d) providing a metallic conductive composition; (e) depositing said conductive composition on said aluminum nitride article; and (f) firing said aluminum nitride article and said conductive composition. 2. A multilayer circuit formed by the method of claim 1. 3. An article comprising a thick film composition comprising a dispersion of finely divided solids comprising: (a) A Pb-free and Cd-free glass composition comprising, in mol %, 1-10% MO where M is selected from Ba, Sr, Ca and mixtures thereof, 5-30% MgO, 0.3-5% CuO, 0-2.5% P2O5, 0-2.5% ZrO2 , 24-45% ZnO, 2-10% Al2O3, 35-50% SiO2 and 0.1-3% A2O where A is one or more alkali elements, and (b) an organic medium comprising a polymeric binder and a volatile organic solvent; wherein said thick film composition is processed to volatilize the organic solvent and sinter the glass composition. 4. A multilayer circuit comprising a plurality of internal thick film metallic conductive composition layers separated by layers of a thick film composition comprising a dispersion of finely divided solids comprising: (a) a lead-free and cadmium-free glass composition comprising, in mol %, 1-10% MO where M is selected from Ba, Sr, Ca and mixtures thereof, 5-30% MgO, 0.3-5% CuO, 0-2.5% P2O5, 0-2.5% ZrO2, 24-45% ZnO, 2-10% Al2O3, 35-50% SiO2 and 0.1-3% A2O where A is one or more alkali elements, and (b) an organic medium comprising a polymeric binder and a volatile organic solvent; wherein said thick film composition is processed to volatilize the organic solvent and sinter the glass composition. 5. The multilayer circuit of any one of claim 2 or 4, wherein said metallic conductive composition comprises Ag. 6. The multilayer circuit of any one of claim 2 or 4, wherein said metallic conductive composition comprises Au. 7. A method of forming a green tape by casting a layer of a thick film composition, comprising a dispersion of finely divided solids comprising: (a) a Pb-free and Cd-free glass composition comprising, in mol %, 1-10% MO where M is selected from Ba, Sr, Ca and mixtures thereof, 5-30% MgO, 0.3-5% CuO, 0-2.5% P2O5, 0-2.5% ZrO2 , 24-45% ZnO, 2-10% Al2O3, 35-50% SiO2 and 0.1-3% A2O where A is one or more alkali elements, and (b) an organic medium comprised of polymeric binder, volatile organic solvent and optional materials such as plasticizers, release agents, dispersing agents, stripping agents, anti-foaming agents and wetting agents; onto a flexible substrate and heating the green tape to remove the volatile organic solvent therefrom. 8. A method of forming a green tape by casting a thin layer of dispersion of finely divided solids comprising: (a) a Pb-free and Cd-free glass composition comprising, in mol %, 1-10% MO where M is selected from Ba, Sr, Ca and mixtures thereof, 5-30% MgO, 0.3-5% CuO, 0-2.5% P2O5, 0-2.5% ZrO2 , 24-45% ZnO, 2-10% Al2O3, 35-50% SiO2 and 0.1-3% A2O where A is one or more alkali elements, and (b) an organic medium comprised of polymeric binder, volatile organic solvent and optional materials such as plasticizers, release agents, dispersing agents, stripping agents, anti-foaming agents and wetting agents; onto a flexible substrate, heating the green tape to remove the volatile organic solvent therefrom and separating the green tape from the flexible substrate. 9. The green tape formed by the method of any one of claim 7 or 8. 10. A method of forming a multilayer interconnection comprising the steps of: (a) forming a patterned array of vias in a plurality of layers of green tape made by casting a thin layer of a dispersion of finely divided solids comprising: (i) a Pb-free and Cd-free glass composition comprising, in mol %, 1-10% MO where M is selected from Ba, Sr, Ca and mixtures thereof, 5-30% MgO, 0.3-5% CuO, 0-2.5% P2O5, 0-2.5% ZrO2 , 24-45% ZnO, 2-10% Al2O3, 35-50% SiO2 and 0.1-3% A2O where A is one or more alkali elements, and (ii) an organic medium comprised of polymeric binder, volatile organic solvent and optional materials such as plasticizers, release agents, dispersing agents, stripping agents, anti-foaming agents and wetting agents; onto a flexible substrate, heating the green tape to remove the volatile organic solvent therefrom and separating the green tape from the flexible substrate; (b) filling said vias in the green tape layer(s) of step (a) with a thick film conductor composition; (c) printing at least one patterned thick film conductor over a surface of each of the via-filled green tape layers of step (b); (d) laminating the printed green tape layers of step (c) to form an assemblage comprising a plurality of interconnected conductor patterned layers separated by the green tape; and (e) cofiring the assemblage of step (d). 11. The multilayer interconnection formed by the method of claim 10.