A semiconductor structure is provided. The semiconductor structure includes a first semiconductor device. The first semiconductor device includes a first bonding layer formed below a first substrate, a first bonding via formed through the first oxide layer and the first bonding layer, a first dummy pad formed in the first bonding layer. The semiconductor structure includes a second semiconductor device. The second semiconductor device includes a second bonding layer formed over a second substrate, a second bonding via formed through the second bonding layer, and a second dummy pad formed in the second bonding layer. The semiconductor structure includes a bonding structure between the first substrate and the second substrate, wherein the bonding structure includes the first bonding via bonded to the second bonding via and the first dummy pad bonded to the second dummy pad.

Various embodiments of the present disclosure are directed towards a semiconductor device structure including a bump structure overlying a bond pad. The bond pad is disposed over a semiconductor substrate. An etch stop layer overlies the bond pad. A buffer layer is disposed over the bond pad and separates the etch stop layer and the bond pad. The bump structure includes a base portion contacting an upper surface of the bond pad and an upper portion extending through the etch stop layer and the buffer layer. The base portion of the bump structure has a first width or diameter and the upper portion of the bump structure has a second width or diameter. The first width or diameter being greater than the second width or diameter.

A microelectronic device includes a metal layer on a first dielectric layer. An etch stop layer is disposed over the metal layer and on the dielectric layer directly adjacent to the metal layer. The etch stop layer includes a metal oxide, and is less than 10 nanometers thick. A second dielectric layer is disposed over the etch stop layer. The second dielectric layer is removed from an etched region which extends down to the etch stop layer. The etched region extends at least partially over the metal layer. In one version of the microelectronic device, the etch stop layer may extend over the metal layer in the etched region. In another version, the etch stop layer may be removed in the etched region. The microelectronic device is formed by etching the second dielectric layer using a plasma etch process, stopping on the etch stop layer.

In a described example, a device includes an overcoat layer covering an interconnect; an opening in the overcoat layer exposing a portion of a surface of the interconnect; a stud on the exposed portion of the surface of the interconnect in the opening; a surface of the stud approximately coplanar with a surface of the overcoat layer; and a conductive pillar covering the stud and covering a portion of the overcoat layer surrounding the stud, the conductive pillar having a planar and un-dished surface facing away from the stud and the overcoat layer.

The present disclosure discloses a semiconductor structure having an insulating layer disposed on a wafer active surface of a semiconductor wafer for covering the wafer active surface. The insulating layer may be a protective layer in some embodiments and a cover layer in other embodiments. The insulating layer has via openings to expose contact pads for leading out electrical connections. In particular, the via openings are formed by a multi-step etching process (such as a two-step etching process) without damaging the contact pads. The two-step etching process includes a first laser etching process using normal pulse (P) and normal energy to form partial via openings in the cover layer. The second etching process includes either a laser etching process using low P and low E or a plasma etching process. The second etching process avoids damaging the contact pads.

Various embodiments of the present disclosure are directed towards a semiconductor structure including a bond bump disposed on an upper surface of an upper conductive structure. The upper conductive structure overlies a substrate. A buffer layer is disposed along the upper surface of the upper conductive structure. The bond bump comprises a sidewall having a straight sidewall segment overlying a curved sidewall segment.

A semiconductor device structure includes a silicon layer disposed over a first semiconductor die, and a first mask layer disposed over the silicon layer. The semiconductor device structure also includes a second semiconductor die disposed over the first mask layer, and a through silicon via penetrating through the silicon layer and the first mask layer. A bottom surface of the through silicon via is greater than a top surface of the through silicon via, and the top surface of the through silicon via is greater than a cross-section of the through silicon via between and parallel to the top surface and the bottom surface of the through silicon via.

The present disclosure, in some embodiments, relates to a method of forming an integrated chip. The method includes forming a plurality of bond pad structures over an interconnect structure on a front-side of a semiconductor body. The plurality of bond pad structures respectively have a titanium contact layer. The interconnect structure and the semiconductor body are patterned to define trenches extending into the semiconductor body. A dielectric fill material is formed within the trenches. The dielectric fill material is etched to expose the titanium contact layer prior to bonding the semiconductor body to a carrier substrate. The semiconductor body is thinned to expose the dielectric fill material along a back-side of the semiconductor body and to form a plurality of integrated chip die. The dielectric fill material is removed to separate the plurality of integrated chip die.

A display device includes a substrate including a display area and a pad area; a first conductive layer including a first pad electrode in the pad area; and a second conductive layer the second conductive layer includes a second pad electrode on the first pad electrode in the pad area; the first pad electrode and the second pad electrode overlap in a first direction that is a thickness direction, and do not overlap in a second direction perpendicular to the first direction.

The present application provides a semiconductor device. The semiconductor device includes a bonding pad disposed over a semiconductor substrate; a first spacer disposed over a top surface of the bonding pad; a second spacer disposed over a sidewall of the bonding pad; a dielectric layer between the bonding pad and the semiconductor substrate. The dielectric layer includes silicon-rich oxide; and a conductive bump disposed over the first passivation layer. The conductive bump is electrically connected to a source/drain (S/D) region in the semiconductor substrate through the bonding pad. The semiconductor device also includes a dielectric liner disposed between the first spacer and the bonding pad; and a first passivation layer covering the second spacer, wherein the dielectric liner is L-shaped, and the first spacer is separated from the bonding pad by the dielectric liner.