A semiconductor device includes a substrate having first and second surfaces, first to third conductive line structures disposed on the first surface, extending in a first direction, and spaced apart from each other in a second direction, and a SRAM unit cell disposed on the first surface, and including first and second inverters connected to each other, a first pass transistor connected to the first inverter, a second pass transistor connected to the second inverter, a first gate electrode included in the first inverter, and a second gate electrode included in the first pass transistor, the first inverter and the first pass transistor are disposed between the first and third conductive line structures, the second inverter and the second pass transistor are disposed between the second and third conductive line structures, and the first and second gate electrodes are disposed between the first and third conductive line structures.

A 3D semiconductor memory device includes a first through-structure on a substrate, the first through-structure comprising first and second conductive pillars spaced apart from each other in a first direction, an electrode adjacent to the first through-structure, the electrode horizontally extending in the first direction, and a ferroelectric layer and a channel layer between the electrode and the first and second conductive pillars. The channel layer connects the first and second conductive pillars to each other. The ferroelectric layer is disposed between the electrode and the channel layer. The ferroelectric layer extends from a sidewall of the first conductive pillar to a sidewall of the second conductive pillar along the channel layer when viewed in a plan view.

A bonded assembly includes first memory die bonded to a logic die. The first memory die includes a first alternating stack of first insulating layers and first electrically conductive layers, first memory openings vertically extending through the first alternating stack, first memory opening fill structures located within the first memory openings and containing a respective vertical stack of first memory elements and a respective vertical semiconductor channel, electrically conductive first side-contact via structures vertically extending through each layer within the first alternating stack and contacting a sidewall of a respective one of the first electrically conductive layers, and first memory-side bonding pads. The logic die includes a peripheral circuitry configured to control operation of the first memory die, logic-side metal interconnect structures, and logic-side bonding pads that are bonded to the first memory-side bonding pads.

Small sized and closely pitched features can be formed by patterning a layer to have holes therein and then expanding the layer so that the holes shrink. If the expansion is sufficient to pinch off the respective holes, multiple holes can be formed from one larger hole. Holes smaller and of closer pitch than practical or possible may be obtained in this way. One process for expanding the layer includes implanting a dopant species having a larger average atomic spacing than does the material of the layer.

A semiconductor device includes a stack structure having gate electrodes and interlayer insulating layers, the stack structure having a cell region and a step region, and the gate electrodes extending in a first direction to have a step shape in the step region, channel structures through the stack structure in the cell region, separation structures through the stack structure and extending in the first direction, and support structures between the separation structures and through the stack structure in the step region. The step region includes first and second regions, the first region closer to the cell region in the first direction than the second region is, the support structures include first and second support structures through the stack structure in the first and second regions, respectively, a maximum width of the first support structure being greater than that of the second support structure.

A semiconductor memory device includes a substrate, contact electrodes extending in a first direction, each of the contact electrodes including a connection portion having a first thickness and a landing portion having a second thickness, an uppermost contact electrode above the contact electrodes, the contact electrodes being longer in the first direction than the uppermost contact electrode and defining a step structure, transistor bodies extending in a second direction and having a first source/drain, a monocrystalline channel layer, and a second source/drain sequentially arranged in the second direction, the monocrystalline channel layer being connected to a corresponding contact electrode, a lower electrode layer connected to the second source/drain of each of the transistor bodies, a capacitor dielectric layer covering the lower electrode layer and having a uniform thickness, and an upper electrode layer separated from the lower electrode layer by the capacitor dielectric layer.

A package structure is provided. The package structure includes a first interconnect structure formed over a first substrate. The package structure also includes a second interconnect structure formed below a second substrate. The package structure further includes a bonding structure between the first interconnect structure and the second interconnect structure. In addition, the bonding structure includes a first intermetallic compound (IMC) and a second intermetallic compound (IMC). The bonding structure also includes an underfill layer surrounding the bonding structure. A width of the first IMC is greater than a width of the second IMC, and the underfill layer covers a sidewall of the first IMC and a sidewall of the second IMC.

A 3D semiconductor memory device includes a substrate, a stack structure comprising interlayer dielectric layers and gate electrodes alternately and repeatedly stacked on the substrate, vertical channel structures penetrating the stack structure, a separation structure spaced apart from the vertical channel structures and filling a trench crossing the stack structure, the separation structure comprising a spacer covering an inner sidewall of the trench, and a first conductive contact filling an inner space of the trench surrounded by the spacer, an insulating layer covering the substrate and the stack structure, contact plugs penetrating the insulating layer so as to be connected to the gate electrodes of the stack structure, and a second conductive contact spaced apart from the stack structure and penetrating the insulating layer so as to be connected to a peripheral circuit transistor. A bottom surface of the first conductive contact is at a level lower than a bottom surface of the spacer.

A semiconductor device includes a conductive structure, a first dielectric layer, a second dielectric layer and a liner layer. The conductive structure is located on a substrate. The first dielectric layer covers the conductive structure and the substrate. The second dielectric layer is located on the first dielectric layer. An air gap is present in the first dielectric layer and the second dielectric layer, and is located above the conductive structure. The liner layer covers and surrounds a middle portion of the air gap.

A chip includes one or more first channels extending in a first direction, a first epitaxial (epi) layer coupled to the one or more first channels, a first gate, wherein the one or more first channels pass through the first gate, one or more second channels extending in the first direction, a second epi layer coupled to the one or more second channels, and a second gate, wherein the one or more second channels pass through the second gate. The chip also includes a dielectric wall extending in the first direction, wherein the dielectric wall is disposed between the first epi layer and the second epi layer, and the dielectric wall is disposed between the first gate and the second gate. The chip further includes a backside bridge underneath the first gate and the second gate, wherein the backside bridge couples the first gate and the second gate.