A semiconductor-on-insulator (SOI) structure includes a semiconductor layer over a buried oxide over a handle wafer. A carbon-doped epitaxial layer is in the semiconductor layer. A doped body region is in the semiconductor layer under the carbon-doped epitaxial layer and extending to the buried oxide. The carbon-doped epitaxial layer and the doped body region have a same conductivity type. Alternatively, a doped body region in the semiconductor layer and extending to the buried oxide includes carbon dopants and body dopants, wherein a peak carbon dopant concentration is situated at a first depth, and a peak body dopant concentration is situated at a second depth below the first depth. Alternatively, an SOI transistor in the semiconductor layer includes a halo region having a different conductivity type from a source and a drain. The halo region includes carbon dopants and body dopants. The source and/or the drain adjoin the halo region.

An integrated device comprising a buried oxide layer within a trench within a top surface of a substrate. A silicon layer formed over the buried oxide layer and the top surface of the substrate.

The present disclosure provides a semiconductor structure, including: a semiconductor device layer including a first surface and a second surface, wherein the first surface is at a front side of the semiconductor device layer, and the second surface is at a backside of the semiconductor device layer; an insulating layer above the second surface of the semiconductor device; and a through-silicon via (TSV) traversing the insulating layer. Associated manufacturing methods of the same are also provided.

A composite substrate includes a substrate, a high-resistance layer located on the substrate, the high-resistance layer comprising a first low-temperature aluminum nitride (AlN) layer, a high-temperature AlN layer and a second low-temperature AlN layer which are stacked in sequence, and a growth substrate located on a side, away from the substrate, of the high-resistance layer. Under the action of the first low-temperature AlN layer, a tensile stress on the high-temperature AlN layer may be reduced, to reduce a dislocation, and further improve a crystal quality of the high-temperature AlN layer and ensure resistivity of the high-temperature AlN layer; and an element of Al in the high-temperature AlN layer is prevented from diffusing into the growth substrate, to protect the crystal quality of the high-temperature AlN layer and improve a bonding effect between the high-resistance layer and the growth substrate. Thus, stability and reliability of the composite substrate are greatly improved.

A bonding apparatus configured to bond substrates includes a first holder configured to vacuum-exhaust a first substrate to attract and hold the first substrate on a bottom surface thereof; a second holder disposed under the first holder, and configured to vacuum-exhaust a second substrate to attract and hold the second substrate on a top surface thereof; a mover configured to move the first holder and the second holder relatively in a horizontal direction; a laser interferometer system configured to measure a position of the first holder or the second holder which is moved by the mover; a linear scale configured to measure a position of the mover; and a controller configured to control the mover based on a measurement result of the laser interferometer system and a measurement result of the liner scale.

The present disclosure relates to a semiconductor device, a manufacturing method, an imaging element, and an electronic device capable of reducing manufacturing steps in a stacked structure obtained by stacking two or more semiconductor substrates. The semiconductor device has a stacked structure obtained by stacking at least a first semiconductor substrate in which a first wiring layer is stacked on a first semiconductor layer and a second semiconductor substrate in which a second wiring layer is stacked on a second semiconductor layer. Then, a through via which electrically connects the first semiconductor substrate and the second semiconductor substrate to each other and penetrates at least the first semiconductor layer is formed in an embedded oxide film formed when element isolation of a semiconductor element formed in the first semiconductor layer is performed. The present technology is applicable to, for example, a stacked semiconductor device.

Direct-bonded native interconnects and active base dies are provided. In a microelectronic architecture, active dies or chiplets connect to an active base die via their core-level conductors. These native interconnects provide short data paths, which forgo the overhead of standard interfaces. The system saves redistribution routing as the native interconnects couple in place. The base die may contain custom logic, allowing the attached dies to provide stock functions. The architecture can connect diverse interconnect types and chiplets from various process nodes, operating at different voltages. The base die may have state elements for drive. Functional blocks aboard the base die receive native signals from diverse chiplets, and communicate with all attached chiplets. The chiplets may share processing and memory resources of the base die. Routing blockages are minimal, improving signal quality and timing. The system can operate at dual or quad data rates. The architecture facilitates ASIC, ASSP, and FPGA ICs and neural networks, reducing footprint and power requirements.

A method of forming a support substrate having a charge-trapping layer involves introducing a single-crystal silicon base substrate into a deposition chamber and, without removing the base substrate from the chamber and while flushing the chamber with a precursor gas, forming an intrinsic silicon epitaxial layer on the base substrate, then forming a dielectric layer on the base substrate by introducing a reactive gas into the chamber over a first time period, and then forming a polycrystalline silicon charge-trapping layer on the dielectric layer by introducing a precursor gas into the chamber over a second time period. The time for which the dielectric layer is exposed only to the carrier gas, between the first time period and the second time period, is less than 30 seconds and the formation of the charge-trapping layer is performed at a temperature of between 1010 C. and 1200 C.

Methods and structures relating to bonding wafers using an aluminum nitride bonding layer with embedded metallization features. In some embodiments, the method may comprise forming a bonding layer on a first wafer where the bonding layer is formed of epitaxially grown aluminum nitride and where the first wafer is a silicon-based material and forming one or more metal features into the bonding layer on the first wafer. The first wafer may be hybrid bonded to a second wafer or die with one or more second metal features surrounded by a diffusion barrier layer. The one or more second metal features of the second wafer or die bonds to the one or more metal features of the first wafer. The diffusion barrier layer of the second wafer or die bonds, at least, to the bonding layer of the first wafer.

Methods and structures relating to bonding wafers using an aluminum nitride bonding layer. In some embodiments, the method may comprise forming a bonding layer of aluminum nitride on a first wafer where the aluminum nitride is grown epitaxially onto the first wafer and bonding the first wafer to a second wafer or die using a low temperature bonding process of less than 400 degrees Celsius. The aluminum nitride may be epitaxially grown using a physical vapor deposition (PVD) process, a metal organic chemical vapor deposition (MOCVD) process, or a molecular-beam epitaxy (MBE) process. The carrier wafer may be silicon with a (111) crystal structure orientation or 4H-silicon carbide with a (001) crystal structure orientation at the interface with the bonding layer.