Abstract: Various embodiments of the present disclosure are directed towards a semiconductor structure including a photodetector disposed within a substrate. A grid structure is disposed over the substrate and the photodetector. A conductive layer is disposed between the grid structure and the substrate. A conductive contact extends into an upper surface of the substrate. The conductive layer is directly electrically coupled to the conductive contact.

Abstract: A method of forming a photoresist pattern includes forming a protective layer over a photoresist layer formed on a substrate. The protective layer and the photoresist layer are selectively exposed to actinic radiation. The photoresist layer is developed to form a pattern in the photoresist layer. The protective layer includes a polymer without a nitrogen-containing moiety, and a basic quencher, an organic acid, a photoacid generator, or a thermal acid generator.

Abstract: An optical device includes a substrate, a first electrode, a second electrode, and a first lens. The first electrode and the second electrode are over the substrate and configured to generate a first electric field. The first lens is between the first electrode and the second electrode and has a focal length that varies in response to the first electric field applied to the first lens.

Abstract: A grid structure in a pixel array may be at least partially angled or tapered toward a top surface of the grid structure such that the width of the grid structure approaches a near-zero width near the top surface of the grid structure. This permits the spacing between color filter regions in between the grid structure to approach a near-zero spacing near the top surfaces of the color filter regions. The tight spacing of color filter regions provided by the angled or tapered grid structure provides a greater surface area and volume for incident light collection in the color filter regions. Moreover, the width of the grid structure may increase at least partially toward a bottom surface of the grid structure such that the wider dimension of the grid structure near the bottom surface of the grid structure provides optical crosstalk protection for the pixel sensors in the pixel array.

Abstract: A pixel sensor may include a layer stack to reduce and/or block the effects of plasma and etching on a photodiode and/or other lower-level layers. The layer stack may include a first oxide layer, a layer having a band gap that is approximately less than 8.8 electron-Volts (eV), and a second oxide layer. The layer stack may reduce and/or prevent the penetration and absorption of ultraviolet photons resulting from the plasma and etching processes, which may otherwise cause the formation of electron-hole pairs in the substrate in which the photodiode is included.

Abstract: The present disclosure, in some embodiments, relates to a metal-insulator-metal (MIM) capacitor structure. The MIM capacitor structure includes one or more lower interconnects disposed within a lower dielectric structure over a substrate. A first dielectric layer is over the lower dielectric structure and includes sidewalls defining a plurality of openings extending through the first dielectric layer. A lower electrode is arranged along the sidewalls and over an upper surface of the first dielectric layer, a capacitor dielectric is arranged along sidewalls and an upper surface of the lower electrode, and an upper electrode is arranged along sidewalls and an upper surface of the capacitor dielectric. A spacer is along opposing outermost sidewalls of the upper electrode. The spacer has an outermost surface extending from a lowermost surface of the spacer to a top of the spacer. The outermost surface is substantially aligned with an outermost sidewall of the lower electrode.

Abstract: The present disclosure, in some embodiments, relates to a method of forming a capacitor structure. The method includes forming a capacitor dielectric layer over a lower electrode layer, and forming an upper electrode layer over the capacitor dielectric layer. The upper electrode layer is etched to define an upper electrode and to expose a part of the capacitor dielectric layer. A spacer structure is formed over horizontally extending surfaces of the upper electrode layer and the capacitor dielectric layer and also along sidewalls of the upper electrode. The spacer structure is etched to remove the spacer structure from over the horizontally extending surfaces of the upper electrode layer and the capacitor dielectric layer and to define a spacer. The capacitor dielectric layer and the lower electrode layer are etched according to the spacer to define a capacitor dielectric and a lower electrode.

Abstract: An image sensor includes a first photodiode and a second photodiode. The image sensor further includes a first color filter over the first photodiode; and a second color filter over the second photodiode. The image sensor further includes a first microlens over the first color filter and a second microlens over the second color filter. The image sensor further includes a first electro-optical (EO) film between the first color filter and the first microlens, wherein a material of the first EO film is configured to change refractive index in response to application of an electrical field. The image sensor further includes a second EO film between the second color filter and the second microlens, wherein a material of the second EO film is configured to change refractive index in response to application of an electrical field.

Abstract: The present disclosure relates to an integrated chip. The integrated chip includes an image sensing element disposed within a substrate. The substrate has a plurality of protrusions disposed along a first side of the substrate over the image sensing element and a ridge disposed along the first side of the substrate. The ridge continuously extends around the plurality of protrusions.

Abstract: A method includes forming image sensors in a semiconductor substrate. A first alignment mark is formed close to a front side of the semiconductor substrate. The method further includes performing a backside polishing process to thin the semiconductor substrate, forming a second alignment mark on the backside of the semiconductor substrate, and forming a feature on the backside of the semiconductor substrate. The feature is formed using the second alignment mark for alignment.

Abstract: Various embodiments of the present disclosure are directed towards a semiconductor structure including a photodetector disposed within a substrate. A grid structure is disposed over the substrate and the photodetector. A conductive layer is disposed between the grid structure and the substrate. A conductive contact extends into an upper surface of the substrate. The conductive layer is directly electrically coupled to the conductive contact.

Abstract: A grid structure in a pixel array may be at least partially angled or tapered toward a top surface of the grid structure such that the width of the grid structure approaches a near-zero width near the top surface of the grid structure. This permits the spacing between color filter regions in between the grid structure to approach a near-zero spacing near the top surfaces of the color filter regions. The tight spacing of color filter regions provided by the angled or tapered grid structure provides a greater surface area and volume for incident light collection in the color filter regions. Moreover, the width of the grid structure may increase at least partially toward a bottom surface of the grid structure such that the wider dimension of the grid structure near the bottom surface of the grid structure provides optical crosstalk protection for the pixel sensors in the pixel array.

Abstract: A pixel sensor may include a layer stack to reduce and/or block the effects of plasma and etching on a photodiode and/or other lower-level layers. The layer stack may include a first oxide layer, a layer having a band gap that is approximately less than 8.8 electron-Volts (eV), and a second oxide layer. The layer stack may reduce and/or prevent the penetration and absorption of ultraviolet photons resulting from the plasma and etching processes, which may otherwise cause the formation of electron-hole pairs in the substrate in which the photodiode is included.

Abstract: A method includes forming image sensors in a semiconductor substrate. A first alignment mark is formed close to a front side of the semiconductor substrate. The method further includes performing a backside polishing process to thin the semiconductor substrate, forming a second alignment mark on the backside of the semiconductor substrate, and forming a feature on the backside of the semiconductor substrate. The feature is formed using the second alignment mark for alignment.

Abstract: The present disclosure, in some embodiments, relates to a method of forming a capacitor structure. The method includes forming a capacitor dielectric layer over a lower electrode layer, and forming an upper electrode layer over the capacitor dielectric layer. The upper electrode layer is etched to define an upper electrode and to expose a part of the capacitor dielectric layer. A spacer structure is formed over horizontally extending surfaces of the upper electrode layer and the capacitor dielectric layer and also along sidewalls of the upper electrode. The spacer structure is etched to remove the spacer structure from over the horizontally extending surfaces of the upper electrode layer and the capacitor dielectric layer and to define a spacer. The capacitor dielectric layer and the lower electrode layer are etched according to the spacer to define a capacitor dielectric and a lower electrode.

Abstract: Various embodiments of the present disclosure are directed towards a method for manufacturing a semiconductor structure. The method includes forming photodetectors within a semiconductor substrate. A charge release layer is deposited over the semiconductor substrate. A conductive contact is formed over the charge release layer such that a contact protrusion of the conductive contact extends through the charge release layer. The charge release layer is disposed along opposing sidewalls of the conductive contact. The charge release layer is electrically coupled to ground via the conductive contact.

Abstract: The present disclosure describes the formation of a pad structure in an image sensor device using a sacrificial isolation region and a silicon oxide based stack with no intervening nitride etch-stop layers. The image sensor device includes a semiconductor layer comprising a first horizontal surface opposite to a second horizontal surface; a metallization layer formed on the second horizontal surface of the semiconductor layer, where the metallization layer includes a dielectric layer. The image sensor device also includes a pad region traversing through the semiconductor layer from the first horizontal surface to the second horizontal surface. The pad region includes an oxide layer with no intervening nitride layers formed on the dielectric layer of the metallization layer and a pad structure in physical contact with a conductive structure of the metallization layer.

Abstract: A method includes forming image sensors in a semiconductor substrate. A first alignment mark is formed close to a front side of the semiconductor substrate. The method further includes performing a backside polishing process to thin the semiconductor substrate, forming a second alignment mark on the backside of the semiconductor substrate, and forming a feature on the backside of the semiconductor substrate. The feature is formed using the second alignment mark for alignment.

Abstract: Various embodiments of the present disclosure are directed towards a method for manufacturing a semiconductor structure. The method includes forming photodetectors within a semiconductor substrate. A charge release layer is deposited over the semiconductor substrate. A conductive contact is formed over the charge release layer such that a contact protrusion of the conductive contact extends through the charge release layer. The charge release layer is disposed along opposing sidewalls of the conductive contact. The charge release layer is electrically coupled to ground via the conductive contact.

Abstract: The present disclosure relates to an integrated chip. The integrated chip includes an image sensing element disposed within a substrate. The substrate has a plurality of protrusions disposed along a first side of the substrate over the image sensing element and a ridge disposed along the first side of the substrate. The ridge continuously extends around the plurality of protrusions.