Memory devices might include an array of memory cells and a control logic to control access of the array of memory cells, where a memory cell of the array of memory cells might include a first dielectric adjacent a semiconductor, a control gate, a second dielectric between the control gate and the first dielectric, and a charge storage structure between the first dielectric and the second dielectric, wherein the charge storage structure comprises a charge-storage material and a gettering agent.

A semiconductor device includes a plurality of nonvolatile memory cells (1). Each of the nonvolatile memory cells comprises a MOS type first transistor section (3) used for information storage, and a MOS type second transistor section (4) which selects the first transistor section. The second transistor section has a bit line electrode (16) connected to a bit line, and a control gate electrode (18) connected to a control gate control line. The first transistor section has a source line electrode (10) connected to a source line, a memory gate electrode (14) connected to a memory gate control line, and a charge storage region (11) disposed directly below the memory gate electrode. A gate withstand voltage of the second transistor section is lower than that of the first transistor section. Assuming that the thickness of a gate insulating film of the second transistor section is defined as tc and the thickness of a gate insulating film of the first transistor section is defined as tm, they have a relationship of tc<tm.

Disclosed herein is a non-volatile storage system with memory cells having a charge storage region that may be configured to store a higher density of charges (e.g., electrons) in the middle than nearer to the control gate or channel. The charge storage region has a middle charge storage material that stores a higher density of charges than two outer charge storage materials that are nearer to the control gate or channel, in one aspect. The charge storage region of one aspect has oxide regions between the middle charge storage material and the two outer charge storage materials. The oxide regions of one embodiment are thin (e.g., less than one nanometer) such that during operation charges may easily pass through the oxide regions. The non-volatile memory cell programs quickly and has high data retention.

A semiconductor memory device includes a channel layer, a gate electrode spaced apart from the channel layer, a blocking insulating layer between the gate electrode and the channel layer, a tunnel insulating layer between the channel layer and the blocking insulating layer, and nano-particles spaced apart from each other between the tunnel insulating layer and the blocking insulating layer.

Apparatus having a processor and a memory device in communication with the processor, the memory device including an array of memory cells and a control logic to control access of the array of memory cells, wherein the array of memory cells includes a memory cell having a first dielectric adjacent a semiconductor, a control gate, a second dielectric between the control gate and the first dielectric, and a charge storage structure between the first dielectric and the second dielectric, and wherein the charge storage structure includes a charge-storage material and a gettering agent.

There is provided a monolithic three dimensional array of charge storage devices which includes a plurality of device levels, wherein at least one surface between two successive device levels is planarized by chemical mechanical polishing.

A method of forming a 3D NAND structure having self-aligned nanodots includes depositing alternating layers of an oxide and a nitride on a substrate; at least partially recessing the nitride layers; and forming SiGe nanodots on the nitride layers. A method of forming a 3D NAND structure having self-aligned nanodots includes depositing alternating layers of an oxide and a nitride on a substrate; at least partially recessing the nitride layers; and forming SiGe nanodots on the nitride layers by a process including maintaining a temperature of the substrate below about 560 C.; flowing a silicon epitaxy precursor into the chamber; forming a silicon epitaxial layer on the substrate at the nitride layers; flowing germanium gas into the chamber with the silicon epitaxy precursor; and forming a silicon germanium epitaxial layer on the substrate at the nitride layers.

According to one embodiment, a semiconductor memory includes: a first gate of a first select transistor and a second gate of a second select transistor on a gate insulating film on a semiconductor layer; an oxide semiconductor layer above the semiconductor layer; a first control gate of a first cell and a second control gate of a second cell on an insulating layer on the oxide semiconductor layer; a third gate of a first transistor between the first control gate and the second control gate; a fourth gate of a second transistor between a first end of the oxide semiconductor layer and the second control gate; an interconnect connected to the first end; a source line connected to the first select transistor; and a bit line connected to the second select transistor.

A non-volatile memory device includes a floating gate for charging and discharging of charges over a substrate. The floating gate comprises a linker layer formed over the substrate and including linkers to be bonded to metal ions and metallic nanoparticles formed out of the metal ions over the linker layer.

The semiconductor device including a device isolation layer disposed in a substrate and defining an active region, a first conductive pattern on the active region, an impurity region in the active region on a side of the first conductive pattern, a second conductive pattern on the active region between the impurity region and the first conductive pattern, a first spacer between the first conductive pattern and the second conductive pattern, and a contact plug disposed on and electrically connected to the first conductive pattern may be provided. The second conductive pattern may have a width less than a width of the contact plug.