Abstract: An integrated circuit memory device, including a memory circuit and a peripheral circuit, is described which is suitable for low cost manufacturing. The memory circuit and peripheral circuit for the device are implemented in different layers of a stacked structure. The memory circuit layer and the peripheral circuit layer include complementary interconnect surfaces, which upon mating together establish the electrical interconnection between the memory circuit and the peripheral circuit. The memory circuit layer and the peripheral circuit layer can be formed separately using different processes on different substrates in different fabrication lines. This enables the use of independent fabrication process technologies, one arranged for the memory array, and another arranged for the supporting peripheral circuit. The separate circuitry can then be stacked and bonded together.

Abstract: A bistable resistance random access memory is described for enhancing the data retention in a resistance random access memory member. A dielectric member, e.g. the bottom dielectric member, underlies the resistance random access memory member which improves the SET/RESET window in the retention of information. The deposition of the bottom dielectric member is carried out by a plasma-enhanced chemical vapor deposition or by high-density-plasma chemical vapor deposition. One suitable material for constructing the bottom dielectric member is a silicon oxide. The bistable resistance random access memory includes a bottom dielectric member disposed between a resistance random access member and a bottom electrode or bottom contact plug. Additional layers including a bit line, a top contact plug, and a top electrode disposed over the top surface of the resistance random access memory member. Sides of the top electrode and the resistance random access memory member are substantially aligned with each other.

Abstract: An example of a capacitor includes a series of ridges and trenches and an interconnect region on the integrated circuit substrate. The series of ridges and trenches and the interconnect region have a capacitor foundation surface with a serpentine cross-sectional shape on the series of ridges and trenches. Electrical conductors are electrically connected to the electrode layers from the interconnect region for access to the electrode layers of the capacitor assembly.

Abstract: A memory cell device, of the type that includes a memory material switchable between electrical property states by application of energy, includes first and second electrodes, a plug of memory material (such as phase change material) which is in electrical contact with the second electrode, and an electrically conductive film which is supported by a dielectric form and which is in electrical contact with the first electrode and with the memory material plug. The dielectric form is wider near the first electrode, and is narrower near the phase change plug. The area of contact of the conductive film with the phase change plug is defined in part by the geometry of the dielectric form over which the conductive film is formed. Also, methods for making the device include steps of constructing a dielectric form over a first electrode, and forming a conductive film over the dielectric form.

Abstract: A semiconductor structure includes first and second chips assembled to each other. The first chip includes N of first conductive lines, M of second conductive lines disposed on the first conductive lines, N of third conductive lines perpendicularly on the second conductive lines and parallel to the first conductive lines, N of first vias connected to the first conductive lines, M sets of second vias connected to the second conductive lines, and N sets of third vias connected to the third conductive lines. The second and first conductive lines form an overlapping area. The third conductive lines and N sets of the third vias include at least two groups respectively disposed in a first and a third regions of the overlapping area. M sets of second vias include at least two groups respectively disposed in a second region and a fourth region of the overlapping area.

Abstract: A resistance type memory device is provided. The resistance type memory device includes a first and a second conductors and a metal oxide layer. The metal oxide layer is disposed between the first and the second conductors, and the resistance type memory device is defined in a first resistivity. The resistance type memory device is defined in a second resistivity after a first pulse voltage is applied to the metal oxide layer. The resistance type memory device is defined in a third resistivity after a second pulse voltage is applied to the metal oxide layer. The second resistivity is greater than the first resistivity, and the first resistivity is greater than the third resistivity.

Abstract: A non-volatile memory device on a semiconductor substrate may include a bottom oxide layer over the substrate, a middle layer of silicon nitride over the bottom oxide layer, and a top oxide layer over the middle layer. The bottom oxide layer may have a hydrogen concentration of up to 5E19 cm?3 and an interface trap density of up to 5E11 cm?2 eV?1. The three-layer structure may be a charge-trapping structure for the memory device, and the memory device may further include a gate over the structure and source and drain regions in the substrate.

Abstract: Memory devices are described along with methods for manufacturing and methods for operating. A memory device as described herein includes a plurality of memory cells located between word lines and bit lines. Memory cells in the plurality of memory cells comprise a diode and a metal-oxide memory element programmable to a plurality of resistance states including a first and a second resistance state, the diode of the memory element arranged in electrical series along a current path between a corresponding word line and a corresponding bit line. The device further includes bias circuitry to apply bias arrangements across the series arrangement of the diode and the memory element of a selected memory cell in the plurality of memory cells.

Abstract: A memory cell and a process for manufacturing the same are provided. In the process, a first electrode layer is formed on a conductive layer over a substrate, and then a transition metal layer is formed on the first electrode layer. After that, the transition metal layer is subjected to a plasma oxidation step to form a transition metal oxide layer as a precursor of a data storage layer, and a second electrode layer is formed on the transition metal oxide layer. A memory cell is formed after the second electrode layer, the transition metal oxide layer and the first electrode layer are patterned into a second electrode, a data storage layer and a first electrode, respectively.

Abstract: A semiconductor structure with improved capacitance of bit lines includes a substrate, a stacked memory structure, a plurality of bit lines, a first stair contact structure, a first group of transistor structures and a first conductive line. The first stair contact structure is formed on the substrate and includes conductive planes and insulating planes stacked alternately. The conductive planes are separated from each other by the insulating planes for connecting the bit lines to the stacked memory structure by stairs. The first group of transistor structures is formed in a first bulk area where the bit lines pass through and then connect to the conductive planes. The first group of transistor structures has a first gate around the first bulk area. The first conductive line is connected to the first gate to control the voltage applied to the first gate.

Abstract: A bistable resistance random access memory is described for enhancing the data retention in a resistance random access memory member. A dielectric member, e.g. the bottom dielectric member, underlies the resistance random access memory member which improves the SET/RESET window in the retention of information. The deposition of the bottom dielectric member is carried out by a plasma-enhanced chemical vapor deposition or by high-density-plasma chemical vapor deposition. One suitable material for constructing the bottom dielectric member is a silicon oxide. The bistable resistance random access memory includes a bottom dielectric member disposed between a resistance random access member and a bottom electrode or bottom contact plug. Additional layers including a bit line, a top contact plug, and a top electrode disposed over the top surface of the resistance random access memory member. Sides of the top electrode and the resistance random access memory member are substantially aligned with each other.

Abstract: A semiconductor structure with improved capacitance of bit lines includes a substrate, a stacked memory structure, a plurality of bit lines, a first stair contact structure, a first group of transistor structures and a first conductive line. The first stair contact structure is formed on the substrate and includes conductive planes and insulating planes stacked alternately. The conductive planes are separated from each other by the insulating planes for connecting the bit lines to the stacked memory structure by stairs. The first group of transistor structures is formed in a first bulk area where the bit lines pass through and then connect to the conductive planes. The first group of transistor structures has a first gate around the first bulk area. The first conductive line is connected to the first gate to control the voltage applied to the first gate.

Abstract: A semiconductor structure and a manufacturing method of the same are provided. The semiconductor structure includes a base, a stacked structure and a doped layer. The stacked structure is formed on the base, wherein the stacked structure comprises a plurality of conductive strips and a plurality of insulating strips, one of the conductive strips is located between adjacent two insulating strips, the stacked structure has a first side wall, and a long edge of the first side wall is extended along a channel direction. The doped layer is formed in the first side wall, wherein the doped layer is formed by an ion implantation applied to the first side wall, and an acute angle is contained between an implantation direction of the ion implantation and the first side wall.

Abstract: A resistive random access memory including, an insulating layer, a hard mask layer, a bottom electrode, a memory cell and a top electrode is provided. The insulating layer is disposed on the bottom electrode. The insulating layer has a contact hole having a first width. The hard mask layer has an opening. A portion of the memory cell is exposed from the opening and has a second width smaller than the first width. The top electrode is disposed on the insulating layer and is coupled with the memory cell.

Abstract: A semiconductor structure and a manufacturing method of the same are provided. The semiconductor structure includes a substrate, a gate dielectric layer, a gate structure, a source conductive structure, a drain conductive structure, and a gate conductive structure. The substrate has a channel area. The gate dielectric layer is formed on the channel area, and the gate structure is formed on the gate dielectric layer. The source conductive structure and the drain conductive structure penetrate through the gate structure and are electrically connected to the substrate, and the source conductive structure and the drain conductive structure are electrically isolated from the gate structure. The gate conductive structure is formed on the gate structure. The source conductive structure and the drain conductive structure are separated by a distance which is equal to a length of the channel area.

Abstract: A bistable resistance random access memory is described for enhancing the data retention in a resistance random access memory member. A dielectric member, e.g. the bottom dielectric member, underlies the resistance random access memory member which improves the SET/RESET window in the retention of information. The deposition of the bottom dielectric member is carried out by a plasma-enhanced chemical vapor deposition or by high-density-plasma chemical vapor deposition. One suitable material for constructing the bottom dielectric member is a silicon oxide. The bistable resistance random access memory includes a bottom dielectric member disposed between a resistance random access member and a bottom electrode or bottom contact plug. Additional layers including a bit line, a top contact plug, and a top electrode disposed over the top surface of the resistance random access memory member. Sides of the top electrode and the resistance random access memory member are substantially aligned with each other.

Abstract: Memory devices are described along with methods for manufacturing and methods for operating. A memory device as described herein includes a plurality of memory cells located between word lines and bit lines. Memory cells in the plurality of memory cells comprise a diode and a metal-oxide memory element programmable to a plurality of resistance states including a first and a second resistance state, the diode of the memory element arranged in electrical series along a current path between a corresponding word line and a corresponding bit line. The device further includes bias circuitry to apply bias arrangements across the series arrangement of the diode and the memory element of a selected memory cell in the plurality of memory cells.

Abstract: An example of a capacitor includes a series of ridges and trenches and an interconnect region on the integrated circuit substrate. The series of ridges and trenches and the interconnect region have a capacitor foundation surface with a serpentine cross-sectional shape on the series of ridges and trenches. Electrical conductors are electrically connected to the electrode layers from the interconnect region for access to the electrode layers of the capacitor assembly.

Abstract: A semiconductor structure and a manufacturing method of the same are provided. The semiconductor structure includes a base, a stacked structure and a doped layer. The stacked structure is formed on the base, wherein the stacked structure comprises a plurality of conductive strips and a plurality of insulating strips, one of the conductive strips is located between adjacent two insulating strips, the stacked structure has a first side wall, and a long edge of the first side wall is extended along a channel direction. The doped layer is formed in the first side wall, wherein the doped layer is formed by an ion implantation applied to the first side wall, and an acute angle is contained between an implantation direction of the ion implantation and the first side wall.

Abstract: A semiconductor structure includes first and second chips assembled to each other. The first chip includes N of first conductive lines, M of second conductive lines disposed on the first conductive lines, N of third conductive lines perpendicularly on the second conductive lines and parallel to the first conductive lines, N of first vias connected to the first conductive lines, M sets of second vias connected to the second conductive lines, and N sets of third vias connected to the third conductive lines. The second and first conductive lines form an overlapping area. The third conductive lines and N sets of the third vias include at least two groups respectively disposed in a first and a third regions of the overlapping area. M sets of second vias include at least two groups respectively disposed in a second region and a fourth region of the overlapping area.