A method of manufacturing a composite structure comprises: a) providing a donor substrate of a single-crystal semiconductor material, b) implanting ions into the donor substrate, excluding an annular peripheral region, to form a buried brittle plane, the implantation conditions defining a first thermal budget for obtaining bubbling on a face of the donor substrate and a second thermal budget for obtaining a fracture in the brittle plane, c) forming a stiffening film on the donor substrate, carried out by applying a thermal budget lower than the first thermal budget, the stiffening film being perforated in the form of a mesh, the perforated stiffening film leaving a plurality of zones of the front face bare, d) depositing a carrier substrate on the donor substrate carried out by applying a thermal budget greater than the first thermal budget, and e) separating the donor substrate along the brittle plane.

Trench isolation connectors are disclosed herein for stacked semiconductor structures, and particularly, for stacked semiconductor structures having high voltage devices. An exemplary stacked device arrangement includes a first device substrate having a first device and a second device substrate having a second device. An isolation structure disposed in the second device substrate surrounds the second device. The isolation structure extends through the second device substrate from a first surface of the second device substrate to a second surface of the second device substrate. A conductive connector is disposed in the isolation structure. The conductive connector is connected to the second device and the first device. The conductive connector extends from the first surface of the second device substrate to the second surface of the second device substrate. The first device and the second device may be a first high voltage device and a second high voltage device, respectively.

A first transfer device and a second transfer device are configured to transfer a first substrate and a second substrate in a normal pressure atmosphere. A third transfer device is configured to transfer the first substrate and the second substrate in a decompressed atmosphere. A load lock chamber has accommodation sections allowed to accommodate therein the first substrate and the second substrate, and is allowed to switch an inside of the accommodation sections between the normal pressure atmosphere and the decompressed atmosphere. Multiple gates are respectively disposed on three different sides of the load lock chamber, and allowed to open or close the load lock chamber. The first transfer device, the second transfer device, and the third transfer device carry the first substrate and the second substrate into/out of the load lock chamber through different gates among the multiple gates.

A first transfer device and a second transfer device are configured to transfer a first substrate and a second substrate in a normal pressure atmosphere. A third transfer device is configured to transfer the first substrate and the second substrate in a decompressed atmosphere. A load lock chamber has accommodation sections allowed to accommodate therein the first substrate and the second substrate, and is allowed to switch an inside of the accommodation sections between the normal pressure atmosphere and the decompressed atmosphere. Multiple gates are respectively disposed on three different sides of the load lock chamber, and allowed to open or close the load lock chamber. The first transfer device, the second transfer device, and the third transfer device carry the first substrate and the second substrate into/out of the load lock chamber through different gates among the multiple gates.

In some examples, a device comprises a wafer chuck, a member having a surface facing the wafer chuck, a blade supported by the surface, a first vacuum nozzle extending through the member and having a first vacuum orifice facing a same direction as the surface, and a second vacuum nozzle extending through the member and having a second vacuum orifice facing the same direction as the surface. The first and second vacuum orifices are on opposing sides of the blade.