A transition metal dichalcogenide (TMD) monolayer grown on a growth substrate is directly transferred to a target substrate. Eliminating the use of a carrier wafer in the TMD monolayer transfer process reduces the number of transfers endured by the TMD monolayer from two to one, which can result in less damage to the TMD monolayer. After a TMD monolayer is grown on a growth layer, a protective layer is formed on the TMD monolayer. The protective layer is bonded to the target substrate by a diffusion bonding layer. The direct transfer of TMD monolayers can be repeated to create a stack of TMD monolayers. A stack of TMD monolayers can be used in a field effect transistor, such as a nanoribbon field effect transistor.

A manufacturing method of a semiconductor structure includes the following steps. A first wafer is provided. The first wafer includes a first substrate and a first device layer. A second wafer is provided. The second wafer includes a second substrate and a second device layer. The second device layer is bonded to the first device layer. An edge trimming process is performed on the first wafer and the second wafer to expose a first upper surface of the first substrate and a second upper surface of the first substrate and to form a damaged region in the first substrate below the first upper surface and the second upper surface. The second upper surface is higher than the first upper surface. A first photoresist layer is formed. The first photoresist layer is located on the second wafer and the second upper surface and exposes the first upper surface and the damaged region. The damaged region is removed by using the first photoresist layer as a mask. The first photoresist layer is removed.

A substrate processing system configured to process a substrate includes a first modifying apparatus configured to form, in a combined substrate in which a front surface of a first substrate and a front surface of a second substrate are bonded to each other, an internal modification layer elongated within the first substrate in a plane direction from a center of the first substrate toward at least an edge portion of the first substrate as a removing target; a second modifying apparatus configured to form, within the first substrate, an edge modification layer elongated in a thickness direction of the first substrate along a boundary between the edge portion and a central portion of the first substrate; and a separating apparatus configured to separate a portion of the first substrate at a rear surface side, starting from the internal modification layer.

The benefits of strained semiconductors are combined with silicon-on-insulator approaches to substrate and device fabrication.

A substrate processing system configured to process a substrate includes a first modifying apparatus configured to form, in a combined substrate in which a front surface of a first substrate and a front surface of a second substrate are bonded to each other, an internal modification layer elongated within the first substrate in a plane direction from a center of the first substrate toward at least an edge portion of the first substrate as a removing target; a second modifying apparatus configured to form, within the first substrate, an edge modification layer elongated in a thickness direction of the first substrate along a boundary between the edge portion and a central portion of the first substrate; and a separating apparatus configured to separate a portion of the first substrate at a rear surface side, starting from the internal modification layer.

A method is used to prepare the remainder of a donor substrate, from which a layer has been removed by delamination in a plane weakened by ion implantation. The remainder comprises, on a main face, an annular step corresponding to a non-removed part of the donor substrate. The method comprises the deposition of a smoothing oxide on the main face of the remainder in order to fill the inner space defined by the annular step and to cover at least part of the annular step, as well as heat treatment for densification of the smoothing oxide. A substrate is produced by the method, and the substrate may be used in subsequent processes.