The present invention discloses a semiconductor-on-diamond-on-carrier substrate wafer. The semiconductor-on-diamond-on-carrier wafer comprises: a semiconductor-on-diamond wafer having a diamond side and semiconductor side; a carrier substrate disposed on the diamond side of the semiconductor-on-diamond wafer and including at least one layer having a lower coefficient of thermal expansion (CTE) than diamond; and an adhesive layer disposed between the diamond side of the semiconductor-on-diamond wafer and the carrier substrate to bond the carrier substrate to the semiconductor-on-diamond wafer. The semiconductor-on-diamond-on-carrier substrate wafer has the following characteristics: a total thickness variation of no more than 40 μm; a wafer bow of no more than 100 μm; and a wafer warp of no more than 40 μm.

A package structure and method of forming the same are provided. The package structure includes a die, a first dielectric layer, a second dielectric layer and a conductive terminal. The first dielectric layer covers a bottom surface of the die and includes a first edge portion and a first center portion in contact with the bottom surface of the die. The first edge portion is thicker than the first center portion. The second dielectric layer is disposed on the first dielectric layer and laterally surrounding the die. The second dielectric layer includes a second edge portion on the first edge portion and a second center portion in contact with a sidewall of the die. The second edge portion is thinner than the second center portion. The conductive terminal is disposed over the die and the second dielectric layer and electrically connected to the die.

A bonding apparatus includes a first holder, a second holder, an imaging unit and a moving device. The first holder is configured to hold a first substrate. The second holder is disposed to face the first holder and configured to hold a second substrate to be bonded to the first substrate. The imaging unit includes a first imaging device configured to image a first alignment mark formed on a surface of the first substrate facing the second substrate and a second imaging device configured to image a second alignment mark formed on a surface of the second substrate facing the first substrate. The moving device is configured to move the imaging unit in a first direction and a second direction intersecting with the first direction within a plan region between the first holder and the second holder.

Wafers including a diamond layer and a semiconductor layer having III-Nitride compounds and methods for fabricating the wafers are provided. A nucleation layer, at least one semiconductor layer having III-Nitride compound and a protection layer are formed on a silicon substrate. Then, a silicon carrier wafer is glass bonded to the protection layer. Subsequently the silicon substrate, nucleation layer and a portion of the semiconductor layer are removed. Then, an intermediate layer, a seed layer and a diamond layer are sequentially deposited on the III-Nitride layer. Next, a substrate wafer that includes a glass substrate (or a silicon substrate covered by a protection layer) is glass bonded to the diamond layer. Then, the silicon carrier wafer and the protection layer are removed.

A device includes a device level having a metallization structure coupled to a semiconductor device and a transistor above the device level. The transistor has a body including a single crystal group III-V or group IV semiconductor material, a source structure on a first portion of the body and a drain structure on a second portion of the body, where the source structure is separate from the drain structure. The transistor further includes a gate structure including a first gate structure portion in a recess in the body and a second gate structure portion between the source structure and the drain structure. A source contact is coupled with the source structure and a drain contact is coupled with the drain structure. The source contact is in contact with the metallization structure in the device level.

A method includes depositing a first epitaxial layer of an aluminum gallium nitride (AlGaN) material onto a preliminary substrate and polishing the first layer's surface. Ions are implanted beneath the surface, which is bonded to a seed insulating substrate. Annealing is performed, resulting in second epitaxial layer on preliminary substrate and third epitaxial layer on seed insulating substrate. Third layer's surface is polished to obtain a seed wafer. In some implementations, a fourth epitaxial layer of a second AlGaN material is deposited onto surface of third layer. Fourth layer's surface is polished, and ions are implanted beneath the surface, which is bonded to a product insulating substrate. Annealing is performed, resulting in fifth epitaxial layer on seed insulating substrate and sixth epitaxial layer on product insulating substrate. The sixth layer can be used to obtain an AlGaN product, and the fifth layer can be reused to fabricate additional AlGaN products.

A method for producing a 3D semiconductor device, the method comprising: providing a first level, said first level comprising a first single crystal layer; forming first alignment marks and control circuits in and/or on said first level, wherein said control circuits comprise first single crystal transistors, and wherein said control circuits comprise at least two interconnection metal layers; forming at least one second level disposed on top of said control circuits; performing a first etch step into said second level; and performing additional processing steps to form a plurality of first memory cells within said second level, wherein each of said memory cells comprise at least one second transistors, and wherein said additional processing steps comprise depositing a gate electrode for said second transistors.

A method for producing a 3D semiconductor device including: providing a first level, the first level including a first single crystal layer; forming first alignment marks and control circuits in and/or on the first level, where the control circuits include first single crystal transistors and at least two interconnection metal layers; forming at least one second level disposed above the control circuits; performing a first etch step into the second level; forming at least one third level disposed on top of the second level; performing additional processing steps to form first memory cells within the second level and second memory cells within the third level, where each of the first memory cells include at least one second transistor, where each of the second memory cells include at least one third transistor, and where the additional processing steps include depositing a gate electrode simultaneously for the second and third transistors.

A 3D semiconductor device including: a first single crystal layer including a plurality of first transistors and a first metal layer, where a second metal layer is disposed atop the first metal layer; a plurality of logic gates including the first metal layer and first transistors; a plurality of second transistors disposed atop the second metal layer; a plurality of third transistors disposed atop the second transistors; a top metal layer disposed atop the third transistors; and a memory array including word-lines, where the memory array includes at least four memory mini arrays, where each of the mini arrays includes at least two rows by two columns of memory cells, where each memory cell includes one of the second transistors or one of the third transistors, and where one of the second transistors is self-aligned to one of the third transistors, being processed following a same lithography step.

The technology of this application relates to a silicon carbide substrate, a silicon carbide device, and a substrate thinning method thereof. The method includes: providing a first substrate, where the first substrate is a silicon carbide substrate, and the first substrate has a silicon surface and a carbon surface that are opposite to each other; forming a silicon carbide device on the silicon surface of the first substrate, and forming a protective layer on the silicon carbide device; performing ion implantation on the carbon surface of the first substrate; providing a second substrate; bonding an ion-implanted first substrate to the second substrate; performing high-temperature annealing on the bonded first substrate and the second substrate to combine ions implanted into the first substrate into gas; and performing separation at a position of ion implantation of the first substrate to obtain a thinned first substrate and a separated first substrate.