A bonded assembly includes a first die containing first bonding pads having sidewalls that are laterally bonded to sidewalls of second bonding pads of a second die.

A first semiconductor die includes first bonding pads. The first bonding pads include proximal bonding pads embedded within a first bonding dielectric layer and distal bonding pads having at least part of the sidewall that overlies the first bonding dielectric layer. A second semiconductor die includes second bonding pads. The second bonding pads are bonded to the proximal bonding pads and the distal bonding pads. The proximal bonding pads are bonded to a respective one of a first subset of the second bonding pads at a respective horizontal bonding interface and the distal bonding pads are bonded to a respective one of a second subset of the second bonding pads at a respective vertical bonding interface at the same time. Dielectric isolation structures may vertically extend through the second bonding dielectric layer of the second semiconductor die and contact the first bonding dielectric layer.

A semiconductor memory device includes a first chip having a peripheral transistor and a first insulating layer, and includes a second chip having a stacked structure and a second insulating layer. The stacked structure includes conductive patterns and insulating patterns alternately stacked with each other, the first insulating layer includes a first bonding surface, the second insulating layer includes a second bonding surface contacting the first bonding surface, and the second chip further includes a protrusion protruding from the second bonding surface of the second insulating layer toward the first insulating layer.

The present technology relates to a semiconductor device in which a MIM capacitive element can be formed without any process damage, and a method for manufacturing the semiconductor device. In a semiconductor device, wiring layers of a first multilayer wiring layer formed on a first semiconductor substrate and a second multilayer wiring layer formed on a second semiconductor substrate are bonded to each other by wafer bonding. The semiconductor device includes a capacitive element including an upper electrode, a lower electrode, and a capacitive insulating film between the upper electrode and the lower electrode. One electrode of the upper electrode and the lower electrode is formed with a first conductive layer of the first multilayer wiring layer and a second conductive layer of the second multilayer wiring layer. The present technology can be applied to a semiconductor device or the like formed by joining two semiconductor substrates, for example.

A semiconductor device according to an embodiment includes: a bonding substrate which includes a first chip forming portion having first metal pads provided at a semiconductor substrate and a first circuit connected to the first metal pads, and a second chip forming portion having second metal pads joined to the first metal pads and a second circuit connected to the second metal pads and being bonded to the first chip forming portion; and an insulating film which is filled into a non-bonded region between the first chip forming portion and the second chip forming portion at an outer peripheral portion of the bonding substrate. At least a part of the insulating film contains at least one selected from the group consisting of silicon nitride and nitrogen-containing silicon carbide.

A semiconductor structure includes a first semiconductor die containing a recesses, and a second semiconductor die which is embedded in the recess in the first semiconductor die and is bonded to the first semiconductor die.

A first wafer, a method of fabricating thereof and a wafer stack are disclosed. The first wafer includes a first substrate, a first dielectric layer on the first substrate, first metal layers embedded in the first dielectric layer, first switching holes extending partially through the first dielectric layer and exposing the first metal layers, a first interconnection layer filling up the first switching holes and electrically connected to the first metal layers, a first insulating layer residing on surfaces of both the first dielectric layer and the first interconnection layer, first contact holes extending through the first insulating layer and exposing the first interconnection layer, and a second interconnection layer filling up the first contact holes and electrically connected to the first interconnection layer. Filling the first contact holes and the first switching holes with different interconnection layers reduces the difficulty in fabricating interconnection structures for the first metal layers.

A semiconductor structure and a method of manufacturing the same are provided. The semiconductor structure includes a first semiconductor element and a first bonding structure. The first semiconductor element has a first element top surface and a first element bottom surface opposite to the element top surface. The first bonding structure is disposed adjacent to the element top surface of the first semiconductor element and includes a first electrical connector, a first insulation layer surrounding the first electrical connector, and a first metal layer surrounding the first insulation layer.

A semiconductor package includes: a lower semiconductor chip including a first semiconductor substrate, which includes a first semiconductor device on an active surface thereof and a protrusion defined by a recess region on an inactive surface thereof opposite to the active surface, a plurality of external connecting pads on a bottom surface of the first semiconductor substrate, and a plurality of through-electrodes electrically connected to the plurality of external connecting pads; and at least one upper semiconductor chip stacked on the protrusion of the lower semiconductor chip and electrically connected to the plurality of through-electrodes, the at least one upper semiconductor chip including a second semiconductor substrate which includes a second semiconductor device on an active surface thereof.

At least one polymer material may be employed to facilitate bonding between the semiconductor dies. Plasma treatment, formation of a blended polymer, or formation of polymer hairs may be employed to enhance bonding. Alternatively, air gaps can be formed by subsequently removing the polymer material to reduce capacitive coupling between adjacent bonding pads.