Provided is a read-only memory (ROM) device. The ROM device comprises a substrate that has a plurality of vertical transport field effect transistors (VFETs). The ROM device further comprises an un-activated semiconductor layer provided on each VFET. The un-activated semiconductor layer includes implanted dopants that have not been substantially activated.

A method of manufacturing a semiconductor device includes forming a stacked structure, forming an opening in the stacked structure, forming a preliminary channel layer in the opening, forming a channel layer by performing heat treatment on the preliminary channel layer, etching an inner surface of the channel layer, and performing ozone (O.sub.3) treatment on an etched inner surface of the channel layer.

A read-only memory (ROM) structure is provided. The ROM device structure includes an active region formed over a substrate and a first group of word lines formed over the active region. The first group of word lines includes at least two word lines. The ROM device structure includes a second group of word lines formed on the active region, and the second group of word lines includes at least two word lines. The ROM device structure further includes an isolation line between the first group of word lines and the second group of word lines and over the active region. The first group of word lines, the second group of word lines, and the isolation line are formed in a second metal layer.

A miniaturized transistor having highly stable electrical characteristics is provided. Furthermore, high performance and high reliability of a semiconductor device including the transistor is achieved. The transistor includes a first electrode, a second electrode, a third electrode, an oxide semiconductor layer, a first insulating layer, and a second insulating layer. The transistor includes a first region and a second region surrounded by the first region. In the first region, the first insulating layer, the second electrode, the oxide semiconductor layer, and the second insulating layer are stacked. In the second region, the first electrode, the oxide semiconductor layer, the second insulating layer, and the third electrode are stacked.

We disclose a high voltage semiconductor device comprising a semiconductor substrate of a second conductivity type; a semiconductor drift region of the second conductivity type disposed over the semiconductor substrate, the semiconductor substrate region having higher doping concentration than the drift region; a semiconductor region of a first conductivity type, opposite to the second conductivity type, formed on the surface of the device and within the semiconductor drift region, the semiconductor region having higher doping concentration than the drift region; and a lateral extension of the first conductivity type extending laterally from the semiconductor region into the drift region, the lateral extension being spaced from a surface of the device.

A method of forming a vertical transistor includes forming at least one fin on stacked layers. The stacked layers include a substrate, a doped silicon layer, and an intrinsic layer interposed between the pair of fins and the substrate. The method further includes forming a spacer hardmask over the pair of fins, and forming a bottom spacer. Forming the bottom spacer includes selective oxidation of the SiGe layer.

A method of forming a semiconductor device and resulting structures having closely packed vertical transistors with reduced contact resistance by forming a semiconductor structure on a doped region of a substrate, the semiconductor structure including a gate formed over a channel region of a semiconductor fin. A liner is formed on the gate and the semiconductor fin, and a dielectric layer is formed on the liner. Portions of the liner are removed to expose a top surface and sidewalls of the semiconductor fin and a sidewall of the dielectric layer. A recessed opening is formed by recessing portions of the liner from the exposed sidewall of the dielectric layer. A top epitaxy region is formed on the exposed portions of the semiconductor fin and dielectric layer such that an extension of the top epitaxy region fills the recessed opening. The top epitaxy region is confined between portions of the liner.

A memory device includes a substrate and a memory array. The substrate has a continuous active region. The memory array is disposed in the continuous active region of the substrate and includes a plurality of memory cells, each of which includes a transistor. The transistor has a nano-scaled pillar that extends substantially vertically from the continuous active region of the substrate.

Methods for forming microelectronic devices include forming lower and upper stack structures, each comprising vertically alternating sequences of insulative and other structures arranged in tiers. Lower and upper pillar structures are formed to extend through the lower and upper stack structures, respectively. An opening is formed through the upper stack structure, and at least a portion of the other structures of the upper stack are replaced by (e.g., chemically converted into) conductive structures, which may be configured as select gate structures. Subsequently, a slit is formed, extending through both the upper and lower stack structures, and at least a portion of the other structures of the lower stack structure are replaced by a conductive material within a liner to form additional conductive structures, which may be configured as access lines (e.g., word lines). Microelectronic devices and structures and related electronic systems are also disclosed.

An integrated circuit includes a junction field-effect transistor formed in a semiconductor substrate. The junction field-effect transistor includes a drain region, a source region, a channel region, and a gate region. A first isolating region separates the drain region from both the gate region and the channel region. A first connection region connects the drain region to the channel region by passing underneath the first isolating region in the semiconductor substrate. A second isolating region separates the source region from both the gate region and the channel region. A second connection region connects the source region to the channel region by passing underneath the second isolating region in the semiconductor substrate.