Patent ID: 8303756

Claim:
A method for bonding a glass cap used for sealing active areas formed on a substrate, the method comprising; forming a plurality of recesses on a first surface of the glass cap for sealing the active areas; forming a plurality of light non-transmittable layers directly on a second surface of the glass cap so that the light non-transmittable layers are one-to-one corresponded to only the active areas formed on the substrate and not corresponded to areas between the active areas, wherein the second surface is on the opposite side of the recesses; dispensing a sealant on a glass cap-bonding region of the substrate; bonding the glass cap to the substrate in the state that each active area formed on the substrate is received in each recess of the glass cap; curing the sealant by irradiating ultraviolet rays to the second surface of the glass cap; and dicing the bonded glass cap and the substrate at a location where the glass cap is bonded to the substrate by the sealant to make individual devices, wherein the light non-transmittable layers are formed only over the active areas and not formed over the areas between the active areas; wherein the each active area comprises an organic material layer and a metal layer deposited on the organic material layer, wherein each of the light non-transmittable layers is chrome or molybdenum thin film formed through a sand blasting process, wherein a plurality of metal lines extended to the metal layer are formed on the glass cap-bonding region, and the sealant is disposed under the glass cap and over the metal lines such that the substrate, the metal lines, the sealant and the glass cap are sequentially stacked from bottom to top at the glass cap-bonding region, wherein the ultraviolet rays are irradiated over the glass cap to pass through from the top to the bottom at the glass cap-bonding region such that the ultraviolet rays reach the sealant after penetrating the glass cap without any influence of the metal lines, and wherein each width of the light non-transmittable layers is substantially equal to that of the active area.