Methods for mounting and dismounting thin and/or bowed semiconductor-on-diamond wafers (401) to a carrier (407) are disclosed that flatten said wafers and provide mechanical support to enable efficient semiconductor device processing on said semiconductor-on-diamond wafers.

Large grain polysilicon films can be exfoliated on a handle substrate, such as a glass or glass-ceramic substrate. The large grain polysilicon can have high mobility for device formation, and can be used for backplane of a display or a sensor array for x-ray detection.

A method for producing a semiconductor device is provided. The method includes providing a semiconductor substrate, providing at least one semiconductor device on the substrate, having a back face opposite the semiconductor substrate and a front face towards the semiconductor substrate, providing a contact layer on the back face of the semiconductor device, bonding the contact layer to an auxiliary carrier, and separating the at least one semiconductor device from the substrate. Further, a semiconductor device produced according to the method and an intermediate product are provided.

In various embodiments, a method for processing a wafer is provided. The method includes forming a layer stack, including a support layer and a useful layer and a sacrificial region between them, said sacrificial region having, vis--vis a processing fluid, a lower mechanical and/or chemical resistance than the support layer and than the useful layer. The support layer has a depression, which exposes the sacrificial region. The method further includes forming at least one channel in the exposed sacrificial region by means of the processing fluid. The channel connects the depression to an exterior of the layer stack.

Disclosed herein is an apparatus for processing a substrate that forms a hole in a substrate while reducing a burr in the hole so that a module device can be inserted into the hole to reduce the thickness of a display device, and the display device using the apparatus. The apparatus for processing the substrate comprises a body configured to operably be rotatable, and a cylindrical cutting tip at an end of the body. The bottom surface of the cutting tip is in an acute angle with respect to a contact surface of the substrate to allow formation of a groove at the substrate.

A bonding system includes a substrate transfer device configured to transfer a first substrate and a second substrate in a normal pressure atmosphere, a surface modifying apparatus configured to modify surfaces of the first substrate and the second substrate to be bonded with each other in a depressurized atmosphere, a load lock chamber in which the first substrate and the second substrate are delivered between the substrate transfer device and the surface modifying apparatus and in which an internal atmosphere of the load lock chamber is switchable between an atmospheric pressure atmosphere and the depressurized atmosphere, a surface hydrophilizing apparatus configured to hydrophilize the modified surfaces of the first substrate and the second substrate, and a bonding apparatus configured to bond the hydrophilized surfaces of the first substrate and the second substrate by an intermolecular force.

Methods of forming a semiconductor device and semiconductor device formed by the methods are provided. The methods of forming a semiconductor device may include providing a first substrate and a first bonding layer that is provided on the first substrate, forming a sacrificial pattern and an active pattern on a second substrate, forming a second bonding layer on the active pattern, bonding the second bonding layer onto the first bonding layer, removing the second substrate, and removing the sacrificial pattern to expose the active pattern. Forming the sacrificial pattern and the active pattern on the second substrate may include forming a preliminary sacrificial pattern and the active pattern on the second substrate and oxidizing the preliminary sacrificial pattern. The preliminary sacrificial pattern and the active pattern may be sequentially stacked on the second substrate.

This invention relates to an assemblage of a semiconductor processing apparatus comprising a first aluminum nitride (AlN) component and a second aluminum nitride component, wherein the first and second aluminum nitride components are connected by a joint, said joint comprising a composite glass-ceramic comprising Y.sub.2O.sub.3Al.sub.2O.sub.3SiO.sub.2 (YAS) glass; and at least one of crystalline aluminosilicate and aluminum nitride.

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 3D semiconductor device including: a first level including a first single crystal layer and first transistors, which each include a single crystal channel; a first metal layer with an overlaying second metal layer; a second level including second transistors, overlaying the first level; a third level including third transistors, overlaying the second level; a fourth level including fourth transistors, overlaying the third level, where the second level includes first memory cells, where each of the first memory cells includes at least one of the second transistors, where the fourth level includes second memory cells, where each of the second memory cells includes at least one of the fourth transistors, where the first level includes memory control circuits, where second memory cells include at least four memory arrays, each of the four memory arrays are independently controlled, and at least one of the second transistors includes a metal gate.