A three-dimensional memory device may include an alternating stack of insulating layers and spacer material layers formed over a carrier substrate. The spacer material layers are formed as, or are subsequently replaced with, electrically conductive layers. Memory stack structures are formed through the alternating stack. Each memory stack structure includes a respective vertical semiconductor channel and a respective memory film. Drain regions and bit lines can be formed over the memory stack structures to provide a memory die. The memory die can be bonded to a logic die containing peripheral circuitry for supporting operations of memory cells within the memory die. A distal end of each of the vertical semiconductor channels is physically exposed by removing the carrier substrate. A source layer is formed directly on the distal end each of the vertical semiconductor channels. A bonding pad can be formed on the source layer.

A memory device is provided. The memory device includes an active region in a substrate, an electrically-isolated electrode, and a dielectric layer. The electrically-isolated electrode is disposed over the active region. The dielectric layer is disposed between the electrically-isolated electrode and the active region and has a first dielectric portion having a first thickness and a second dielectric portion having a second thickness.

A memory device is disclosed. The memory device includes: a first memory cell, including: a first transistor; a second transistor; and a first capacitor; a second memory cell, including: a third transistor; a fourth transistor; and a second capacitor; a third memory cell, including: a fifth transistor; a sixth transistor; and a third capacitor; and a fourth memory cell, including: a seventh transistor; an eighth transistor; and a fourth capacitor; wherein an electrode of the first capacitor, an electrode of the second capacitor, an electrode of the third capacitor, and an electrode of the fourth capacitor are electrically connected to a conductor. An associated manufacturing method is also disclosed.

Methods of forming semiconductor devices, memory cells, and arrays of memory cells include forming a liner on a conductive material and exposing the liner to a radical oxidation process to densify the liner. The densified liner may protect the conductive material from substantial degradation or damage during a subsequent patterning process. A semiconductor device structure, according to embodiments of the disclosure, includes features extending from a substrate and spaced by a trench exposing a portion of a substrate. A liner is disposed on sidewalls of a region of at least one conductive material in each feature. A semiconductor device, according to embodiments of the disclosure, includes memory cells, each comprising a control gate region and a capping region with substantially aligning sidewalls and a charge structure under the control gate region.

A nonvolatile memory device may be provided. The nonvolatile memory device comprises an active region, an n-well region and an isolation region separating the active region and the n-well region. A floating gate may be provided. The floating gate may be arranged over a portion of the active region and over a first portion of the n-well region. A first doped region in the active region may be laterally displaced from the floating gate on a first side and a second doped region in the active region may be laterally displaced from the floating gate on a second side opposite to the first side. A contact may be arranged over the n-well region, whereby the contact may be laterally displaced from a first corner of the floating gate over the first portion of the n-well region. A silicide exclusion layer may be arranged at least partially over the floating gate.

A semiconductor memory device includes a select transistor and a floating gate transistor on a substrate. The select transistor includes a select gate, a select gate oxide layer and a drain doping region. The floating gate transistor includes a floating gate, a floating gate oxide layer, a source doping region, a first tunnel doping region and a second tunnel doping region under the floating gate, a first tunnel oxide layer on the first tunnel doping region, and a second tunnel oxide layer on the second tunnel doping region. The floating gate oxide layer is disposed between the first tunnel oxide layer and the second tunnel oxide layer. A lightly doped diffusion region surrounds the source doping region and the second tunnel doping region.

Embodiments of the disclosure provide a circuit structure and related multi-time programmable (MTP) memory cell. The circuit structure may include a transistor having a floating gate over a semiconductor channel and a control gate on the dielectric layer. The control gate is electrically coupled to a word line. The control gate is capacitively coupled to the floating gate. A metal-insulator-metal (MIM) capacitor includes a first electrode coupled to the word line and a second electrode coupled to the floating gate of the transistor.

An integrated circuit includes two different types of embedded memories, with cells that have different retention characteristics, and situated in different areas of the substrate. In some applications the cells are both non-volatile memories sharing a common gate layer but with different oxide layers, different thicknesses, etc. The first type of cell is a conventional flash cell which can be part of a logic/memory region, while the second type of cell uses capacitive coupling and can be located in a high voltage region. Because of their common features, the need for additional masks, manufacturing steps, etc. can be mitigated.

A method used in forming a memory array comprising strings of memory cells comprises forming a stack comprising vertically-alternating insulative tiers and wordline tiers. First charge-blocking material is formed to extend elevationally along the vertically-alternating tiers. The first charge-blocking material has k of at least 7.0 and comprises a metal oxide. A second charge-blocking material is formed laterally inward of the first charge-blocking material. The second charge-blocking material has k less than 7.0. Storage material is formed laterally inward of the second charge-blocking material. Insulative charge-passage material is formed laterally inward of the storage material. Channel material is formed to extend elevationally along the insulative tiers and the wordline tiers laterally inward of the insulative charge-passage material. Structure embodiments are disclosed.

Some embodiments include apparatuses and methods of forming such apparatuses. One of the apparatus includes first memory cells located in different levels in a first portion of the apparatus, second memory cells located in different levels in a second portion of the apparatus, a switch located in a third portion of the apparatus between the first and second portions, first and second control gates to access the first and second memory cells, an additional control gate located between the first and second control gates to control the switch, a first conductive structure having a thickness and extending perpendicular to the levels in the first portion of the apparatus, a first dielectric structure between the first conductive structure and charge-storage portions of the first memory cells, a second dielectric structure having a second thickness between the second conductive structure and a sidewall of the additional control gate, the second thickness being greater than the first thickness.