Provided with a solid state image sensor, which is adapted to simplify the process with enhancement of the morphology of the device and has photo-diodes formed on a semiconductor substrate, and transfer gates disposed around the photo-diodes to transfer signal charges generated from the photo-diodes, the solid state image sensor including: an insulating layer forming on the whole surface of the semiconductor substrate and having a contact hole exposing a defined portion of the transfer gates; a metal line formed to include the inside of the contact hole; and a light-shielding layer formed in the same layer with the metal line without overlapping the upper parts of the photo-diodes.

Provided with a solid state image sensor, which is adapted to simplify the process with enhancement of the morphology of the device and has photo-diodes formed on a semiconductor substrate, and transfer gates disposed around the photo-diodes to transfer signal charges generated from the photo-diodes, the solid state image sensor including: an insulating layer forming on the whole surface of the semiconductor substrate and having a contact hole exposing a defined portion of the transfer gates; a metal line formed to include the inside of the contact hole; and a light-shielding layer formed in the same layer with the metal line without overlapping the upper parts of the photo-diodes.

The present invention is a method for increasing the refresh time of DRAM. This invention is for decreasing the stress between the bird's beak of field oxide and silicon substrate by using fluorine ion implant before field oxidation and the optimal structure of LOCOS to effectively preventing the current leakage from the bird's beak of field oxide. Therefore, this invention can increase the refresh time of DRAM and greatly enhance the performance in DRAM.

A photodiode is provided comprising a substrate, a well with a first electric type within the substrate, a heavily doped region with a second electric type within the well, and a insulating layer on the substrate. The insulating layer in the position on the heavily doped region is thinner than in other positions. A junction is thus formed between the heavily doped region and the well.

A method for creating a lateral overflow drain, anti-blooming structure in a charge-coupled device, the method includes the steps of providing a substrate of a first conductivity type; providing a layer of silicon dioxide on the substrate; providing a layer of silicon nitride on the silicon dioxide layer; providing a first masking layer on the silicon nitride layer and having an opening in the first masking layer of a dimension which substantially equals a dimension of a subsequently implanted channel stop of the first conductivity type; etching away the exposed silicon nitride within the opening in the first masking layer; implanting ions of the first conductivity type through the first masking layer and into the substrate for creating the channel stop and removing the first masking layer; growing the silicon dioxide layer so that the channel stop is spanned by a thickest field silicon dioxide layer in the etched away portion; patterning a second masking layer having an opening adjacent the channel stop with a dimension substantially equal to a dimension of a subsequently implanted lateral overflow drain of a second conductivity type; etching away the exposed silicon nitride within the opening in the second masking layer; implanting the second conductivity type for forming the lateral overflow drain and removing any remaining masking layer; and growing the silicon dioxide layer so that a thicker silicon dioxide forms spanning the lateral overflow drain and the thickest silicon dioxide layer forms spanning the channel stop.