A microelectronic device comprises a stack structure comprising alternating conductive structures and insulative structures arranged in tiers, each of the tiers individually comprising a conductive structure and an insulative structure, strings of memory cells vertically extending through the stack structure, the strings of memory cells comprising a channel material vertically extending through the stack structure, and another stack structure vertically overlying the stack structure and comprising other tiers of alternating levels of other conductive structures and other insulative structures, the other conductive structures exhibiting a conductivity greater than a conductivity of the conductive structures of the stack structure. Related memory devices, electronic systems, and methods are also described.

Forces applied to the channel regions of semiconductor slabs in a first direction relative to the semiconductor slab, can create strains in the crystal structure that improve carrier mobility to improve drive strength in the channel region. In a three-dimensional (3D) FET structure, a work function metal layer is provided on opposing faces of semiconductor slabs to cause a force to be exerted on the channel regions in a first direction corresponding to current flow. The force in the first direction is either tensile force or compressive force, depending on a FET type (N or P) employing the semiconductor slab, and is provided to create strain in a crystalline structure of the semiconductor slab to improve carrier mobility in the channel region. Increasing carrier mobility in the channel regions in a 3D FET structure increases drive strength of the 3D FET, which saves area in an integrated circuit.

In a method of forming a FinFET, a first sacrificial layer is formed over a source/drain structure of a FinFET structure and an isolation insulating layer. The first sacrificial layer is recessed so that a remaining layer of the first sacrificial layer is formed on the isolation insulating layer and an upper portion of the source/drain structure is exposed. A second sacrificial layer is formed on the remaining layer and the exposed source/drain structure. The second sacrificial layer and the remaining layer are patterned, thereby forming an opening. A dielectric layer is formed in the opening. After the dielectric layer is formed, the patterned first and second sacrificial layers are removed to form a contact opening over the source/drain structure. A conductive layer is formed in the contact opening.

The present application discloses a semiconductor device and a method for fabricating the semiconductor device. The semiconductor device includes a substrate; a buried conductive layer including a bottom portion positioned in the substrate, and a top portion positioned in the substrate and positioned on the bottom portion; and an in-recess spacer positioned in the substrate, surrounding the bottom portion, and covered by the top portion. A top surface of the top portion and a top surface of the substrate are substantially coplanar. A bottom surface of the in-recess spacer and a bottom surface of the bottom portion are substantially coplanar. A sidewall of the in-recess spacer and a sidewall of the top portion are substantially coplanar.

The present application discloses a semiconductor device and a method for fabricating the semiconductor device. The semiconductor device includes a substrate; a buried conductive layer including a bottom portion positioned in the substrate, and a top portion positioned in the substrate and positioned on the bottom portion; and an in-recess spacer positioned in the substrate, surrounding the bottom portion, and covered by the top portion. A top surface of the top portion and a top surface of the substrate are substantially coplanar. A bottom surface of the in-recess spacer and a bottom surface of the bottom portion are substantially coplanar. A sidewall of the in-recess spacer and a sidewall of the top portion are substantially coplanar.

Provided is a semiconductor device comprising a diode portion, comprising: a plurality of trench portions provided at a front surface of a semiconductor substrate; a drift region of a first conductivity type provided on the semiconductor substrate; an anode region of a second conductivity type provided above the drift region in the diode portion; a first plug region of the second conductivity type provided above the drift region in the diode portion, which has a doping concentration higher than a doping concentration of the anode region; a front surface side electrode provided above the semiconductor substrate; and an interlayer dielectric film provided above a mesa portion provided between the plurality of trench portions; wherein the anode region is connected to the front surface side electrode on side surfaces of the plurality of trench portions.

A semiconductor device includes a chip having a principal surface, a pn-junction portion extending in a horizontal direction along the principal surface inside the chip, a trench insulating structure formed in the principal surface such that the trench insulating structure penetrates through the pn-junction portion, and demarcating a diode region in the chip, a barrier forming region formed in a surface layer portion of the principal surface in the diode region, and a metal layer located on the principal surface such that the metal layer covers the barrier forming region in the diode region, and forming a Schottky-junction portion with the barrier forming region.

Presented are structures and methods for forming such structures that allow for electrical or diffusion breaks between transistors of one level of a stacked transistor device, without necessarily requiring that a like electrical or diffusion break exists in another level of the stacked transistor device. Also presented, an electrical break between transistor devices may be formed by providing a channel of a first polarity with a false gate comprising a work-function metal of an opposite polarity.

Integrated circuits including MOSFETs with selectively recessed gate electrodes. Transistors having recessed gate electrodes with reduced capacitive coupling area to adjacent source and drain contact metallization are provided alongside transistors with gate electrodes that are non-recessed and have greater z-height. In embodiments, analog circuits employ transistors with gate electrodes of a given z-height while logic gates employ transistors with recessed gate electrodes of lesser z-height. In embodiments, subsets of substantially planar gate electrodes are selectively etched back to differentiate a height of the gate electrode based on a given transistor's application within a circuit.

An electrical device that includes at least one n-type field effect transistor including a channel region in a type III-V semiconductor device, and at least one p-type field effect transistor including a channel region in a germanium containing semiconductor material. Each of the n-type and p-type semiconductor devices may include gate structures composed of material layers including work function adjusting materials selections, such as metal and doped dielectric layers. The field effect transistors may be composed of fin type field effect transistors. The field effect transistors may be formed using gate first processing or gate last processing.