This disclosure relates to dielectric film forming composition containing at least one fully imidized polyimide polymer; at least one inorganic filler; at least one metal-containing (meth)acrylate compound; and at least one catalyst. The dielectric film formed by such a composition can have a relatively low coefficient of thermal expansion (CTE) and a relatively high optical transparency.

This disclosure relates to dielectric film forming composition containing at least one fully imidized polyimide polymer; at least one inorganic filler; at least one metal-containing (meth)acrylate compound; and at least one catalyst. The dielectric film formed by such a composition can have a relatively low coefficient of thermal expansion (CTE) and a relatively high optical transparency.

This disclosure relates to dielectric film forming composition containing at least one fully imidized polyimide polymer; at least one inorganic filler; at least one metal-containing (meth)acrylate compound; and at least one catalyst. The dielectric film formed by such a composition can have a relatively low coefficient of thermal expansion (CTE) and a relatively high optical transparency.

Provided is a maleimide resin with superior solution stability. Also provided is a cured product with a superior dielectric characteristic that is obtained by curing a curable resin composition in which said maleimide resin is used. The maleimide resin expressed in formula (1), wherein the N,N-(phenylene-di-(2,2,-propylidene)-di-p-phenylene) bismaleimide content is 90 area % or less. (In formula (1), n is the number of repetitions, and 1<n<5.)

Provided is a maleimide resin with superior solution stability. Also provided is a cured product with a superior dielectric characteristic that is obtained by curing a curable resin composition in which said maleimide resin is used. The maleimide resin expressed in formula (1), wherein the N,N-(phenylene-di-(2,2,-propylidene)-di-p-phenylene) bismaleimide content is 90 area % or less. (In formula (1), n is the number of repetitions, and 1<n<5.)

Click reactions may be used to bond polymers to lignin by taking advantage of lignin's terminal hydroxyl and thiol groups via an alkyne-azide click reaction or a thiol-alkene or thiol-alkyne click reaction. By selecting functional polymers, these methods may be used to synthesize lignin-containing polymer materials with an array of different properties, such as self-healing polymers.

Click reactions may be used to bond polymers to lignin by taking advantage of lignin's terminal hydroxyl and thiol groups via an alkyne-azide click reaction or a thiol-alkene or thiol-alkyne click reaction. By selecting functional polymers, these methods may be used to synthesize lignin-containing polymer materials with an array of different properties, such as self-healing polymers.

This disclosure relates to dielectric film forming composition containing at least one fully imidized polyimide polymer; at least one inorganic filler; at least one metal-containing (meth)acrylate compound; and at least one catalyst. The dielectric film formed by such a composition can have a relatively low coefficient of thermal expansion (CTE) and a relatively high optical transparency.

This disclosure relates to dielectric film forming composition containing at least one fully imidized polyimide polymer; at least one inorganic filler; at least one metal-containing (meth)acrylate compound; and at least one catalyst. The dielectric film formed by such a composition can have a relatively low coefficient of thermal expansion (CTE) and a relatively high optical transparency.

This disclosure relates to dielectric film forming compositions containing a) at least one fully imidized polyimide polymer; b) at least one metal-containing (meth)acrylates; c) at least one catalyst; and d) at least one solvent, as well as related processes and related products. The compositions can form a dielectric film that generates substantially no debris when the dielectric film is patterned by laser ablation process.