Methods of forming SOI substrates are disclosed. In some embodiments, an epitaxial layer and an oxide layer are formed on a sacrificial substrate. An etch stop layer is formed in the epitaxial layer. The sacrificial substrate is bonded to a handle substrate at the oxide layer. The sacrificial substrate is removed. The epitaxial layer is partially removed until the etch stop layer is exposed.

The present disclosure includes bonded wafer structures and methods of forming bonded wafer structures. One example of a forming a bonded wafer structure includes providing a first wafer (202, 302) and a second wafer (204, 304) to be bonded together via a bonding process that has a predetermined wafer gap (216, 316) associated therewith, and forming a mesa (215, 315, 415) on the first wafer (202, 302) prior to bonding the first wafer (202, 302) and the second wafer (204, 304) together, wherein a height (220, 320, 420) of the mesa (215, 315, 415) is determined based on a target element gap (217, 317) associated with the bonded wafer structure.

A method is disclosed that includes the steps outlined below. An epitaxial layer is formed on a first semiconductor substrate. At least one implant species is implanted between the epitaxial layer and the first semiconductor substrate to form an ion-implanted layer. The epitaxial layer is bonded to a bonding oxide layer of a second semiconductor substrate. The first semiconductor substrate is separated from the ion-implanted layer.

The disclosed technology relates generally to a method and system for micro assembling GaN materials and devices to form displays and lighting components that use arrays of small LEDs and high-power, high-voltage, and or high frequency transistors and diodes. GaN materials and devices can be formed from epitaxy on sapphire, silicon carbide, gallium nitride, aluminum nitride, or silicon substrates. The disclosed technology provides systems and methods for preparing GaN materials and devices at least partially formed on several of those native substrates for micro assembly.

Systems and methods herein relate to the fabrication of a single-crystal flexible semiconductor template that may be attached to a semiconductor device. The template fabricated comprises a plurality of single crystals grown by lateral epitaxial growth on a seed layer and bonded to a flexible substrate. The layer grown has portions removed to create windows that add to the flexibility of the template.

Methods of forming semiconductor structures include providing a polymeric material over a carrier substrate, bonding another substrate to the polymeric material, and lowering a temperature of the polymeric material to below about 15 C. to separate the another substrate from the carrier substrate. Some methods include forming a polymeric material over a first substrate, securing a second substrate to the first substrate over the polymeric material, cooling the polymeric material to a temperature below a glass transition temperature of the polymeric material, and separating the second substrate from the first substrate. Semiconductor structures may include a polymeric material over at least a portion of a first substrate, an adhesive material over the polymeric material, and a second substrate over the adhesive material. The polymeric material may have a glass transition temperature of about 10 C. or lower and a melting point of about 100 C. or greater.

Technologies are generally described related to three-dimensional integration of integrated circuits (ICs) with spacing for heat dissipation. According to some examples, a self-aligned silicide may be formed in a temporary silicon layer and removed subsequent to bonding of the wafers to achieve improved contact between the combined ICs and enhanced heat dissipation through added spacing between the ICs.

A bio-sensing semiconductor structure is provided. A transistor includes a channel region and a gate underlying the channel region. A first dielectric layer overlies the transistor. A first opening extends through the first dielectric layer to expose the channel region. A bio-sensing layer lines the first opening and covers an upper surface of the channel region. A second dielectric layer lines the first opening over the bio-sensing layer. A second opening within the first opening extends to the bio-sensing layer, through a region of the second dielectric layer overlying the channel region. A method for manufacturing the bio-sensing semiconductor structure is also provided.

A method of integrating a first substrate having a first surface with a first insulating material and a first contact structure with a second substrate having a second surface with a second insulating material and a second contact structure. The first insulating material is directly bonded to the second insulating material. A portion of the first substrate is removed to leave a remaining portion. A third substrate having a coefficient of thermal expansion (CTE) substantially the same as a CTE of the first substrate is bonded to the remaining portion. The bonded substrates are heated to facilitate electrical contact between the first and second contact structures. The third substrate is removed after heating to provided a bonded structure with reliable electrical contacts.

A semiconductor wafer is formed with a first device layer having active devices. A handle wafer having a trap rich layer is bonded to a top surface of the semiconductor wafer. A second device layer having a MEMS device or acoustic filter device is formed on a bottom surface of the semiconductor wafer. The second device layer is formed either by monolithic fabrication processes or layer-transfer processes.