There are provided a semiconductor memory device and an erasing method of the semiconductor memory device. The semiconductor memory device includes: a plurality of word lines stacked between a source conductive pattern and a bit line; at least two drain select lines disposed between the plurality word lines and the bit line, the at least two drain select lines being spaced apart from each other in an extending direction of the bit line; and an erase control line disposed between the at least two drain select lines and the plurality of word lines.

An apparatus is provided which comprises: a plurality of dielectric layers forming a substrate, a plurality of first conductive contacts on a first surface of the substrate, a cavity in the first surface of the substrate defining a second surface parallel to the first surface, a plurality of second conductive contacts on the second surface of the substrate, one or more integrated circuit die(s) coupled with the second conductive contacts, and mold material at least partially covering the one or more integrated circuit die(s) and the first conductive contacts. Other embodiments are also disclosed and claimed.

A method and apparatus for laterally urging two semiconductor chips, dies or wafers into an improved state of registration with each other, the method and apparatus employing microstructures comprising: a first microstructure disposed on a first major surface of a first one of said two semiconductor chips, dies or wafers, wherein the first microstructure includes a sidewall which is tapered thereby disposing it at an acute angle compared to a perpendicular of said first major surface, and a second microstructure disposed on a first surface of a second one of said two semiconductor chips, dies or wafers, wherein the shape of the second microstructure is complementary to, and mates with or contacts, in use, the first microstructure, the second microstructure including a surface which contacts said sidewall when the first and second microstructures are mated or being mated, the sidewall of the first microstructure and the surface of the second microstructure imparting a lateral force for urging the two semiconductor chips, dies or wafers into said improved state of registration.

A semiconductor package device includes a first semiconductor package, a second semiconductor package, and first connection terminals between the first and second semiconductor packages. The first semiconductor package includes a lower redistribution substrate, a semiconductor chip, and an upper redistribution substrate vertically spaced apart from the lower redistribution substrate across the semiconductor chip. The upper redistribution substrate includes a dielectric layer, redistribution patterns vertically stacked in the dielectric layer and each including line and via parts, and bonding pads on uppermost redistribution patterns. The bonding pads are exposed from the dielectric layer and in contact with the first connection terminals. A diameter of each bonding pad decreases in a first direction from a central portion at a top surface of the upper redistribution substrate to an outer portion at the top surface thereof. A thickness of each bonding pad increases in the first direction.

Disclosed are semiconductor packages and methods of manufacturing the same. The method of manufacturing a semiconductor package may include providing a carrier substrate having a trench formed on a first top surface of the carrier substrate, providing a first semiconductor chip on the carrier substrate, mounting at least one second semiconductor chip on a second top surface of the first semiconductor chip, coating a mold member to surround a first lateral surface of the first semiconductor chip and a second lateral surface of the at least one second semiconductor chip, and curing the mold member to form a mold layer. The trench may be provided along a first edge of the first semiconductor chip. The mold member may cover a second edge of a bottom surface the first semiconductor chip.

A semiconductor structure and a forming method thereof are provided. One form of a semiconductor structure includes: a first device structure, including a first substrate and a first device formed on the first substrate, the first device including a first channel layer structure located on the first substrate, a first device gate structure extending across the first channel layer structure, and a first source-drain doping region located in the first channel layer structure on two sides of the first device gate structure; and a second device structure, located on a front surface of the first device structure, including a second substrate located on the first device structure and a second device formed on the second substrate, the second device including a second channel layer structure located on the second substrate, a second device gate structure extending across the second channel layer structure, and a second source-drain doping region located in the second channel layer structure on two sides of the second device gate structure, where projections of the second channel layer structure and the first channel layer structure onto the first substrate intersect non-orthogonally. The electricity of the first device can be led out according to the present disclosure.

Provided is a package structure includes a first die, a first dielectric layer, a second dielectric layer and a carrier. The first dielectric layer covers a bottom surface of the first die. The first dielectric layer includes a first edge portion and a first center portion in contact with the bottom surface of the first die. The second dielectric layer is disposed on the first dielectric layer and laterally surrounding the first die. The second dielectric layer includes a second edge portion and a second center portion. The second edge portion is located on the first edge portion, and the second edge portion is thinner than the second center portion. The carrier is bonded to the first dielectric layer through a bonding film.

A semiconductor structure and method for forming the semiconductor are provided. The semiconductor structure includes a first electrode comprising a first portion, a second portion, and a sheet portion connecting the first portion to the second portion. A ferroelectric material is over the sheet portion. A second electrode is over the ferroelectric material.

A device includes a lower semiconductor substrate, a lower gate structure on the lower semiconductor substrate, the lower gate structure comprises a lower gate electrode, a lower interlayer insulating film on the lower semiconductor substrate, an upper semiconductor substrate on the lower interlayer insulating film, an upper gate structure on the upper semiconductor substrate, and an upper interlayer insulating film on the lower interlayer insulating film, the upper interlayer insulating film covers sidewalls of the upper semiconductor substrate The upper gate structure comprises an upper gate electrode extending in a first direction and gate spacers along sidewalls of the upper gate electrode. The upper gate electrode comprises long sidewalls extending in the first direction and short sidewalls in a second direction The gate spacers are on the long sidewalls of the upper gate electrode and are not disposed on the short sidewalls of the upper gate electrode.

The present disclosure relates to a radio frequency device that includes a transfer device die and a multilayer redistribution structure underneath the transfer device die. The transfer device die includes a device region with a back-end-of-line (BEOL) portion and a front-end-of-line (FEOL) portion over the BEOL portion and a transfer substrate. The FEOL portion includes isolation sections and an active layer surrounded by the isolation sections. A top surface of the device region is planarized. The transfer substrate including a porous silicon (PSi) region resides over the top surface of the device region. Herein, the PSi region has a porosity between 1% and 80%. The multilayer redistribution structure includes a number of bump structures, which are at a bottom of the multilayer redistribution structure and electrically coupled to the FEOL portion of the transfer device die.