Memory systems and memory programming methods are described. According to one arrangement, a memory system includes a plurality of memory cells individually configured to have a plurality of different memory states, a plurality of bitlines coupled with the memory cells, access circuitry coupled with the bitlines and configured to apply a plurality of program signals to the bitlines to program the memory cells between the different memory states, a controller configured to control the access circuitry to provide a first program signal and a second program signal to one of the bitlines coupled with one of the memory cells to program the one memory cell from a first of the memory states to a second of the memory states, wherein the second program signal has an increased electrical characteristic compared with the first program signal, and selection circuitry configure to couple another of the bitlines which is immediately adjacent to the one bitline to a node having a first voltage which is different than a second voltage of the one bitline during the provision of the first and second program signals to the one bitline.

The present disclosure, in some embodiments, relates to an integrated chip. The integrated chip includes a first resistive random access memory (RRAM) element and a second RRAM element over a substrate. A conductive element is arranged below the first RRAM element and the second RRAM element. The conductive element electrically couples the first RRAM element to the second RRAM element. An upper insulating layer continuously extends over the first RRAM element and the second RRAM element. An upper inter-level dielectric (ILD) structure laterally surrounds the first RRAM element and the second RRAM element. The upper insulating layer separates the first RRAM element and the second RRAM element from the upper ILD structure.

Provided is a semiconductor device including a substrate, a tunneling insulating film disposed on the substrate, a control gate electrode disposed on the tunneling insulating film, a first floating gate electrode disposed between the control gate electrode and the tunneling insulating film, a second floating gate electrode disposed between the first floating gate electrode and the tunneling insulating film, a first control gate insulating film disposed between the first floating gate electrode and the control gate electrode, a second control gate insulating film disposed between the second floating gate electrode and the first floating gate electrode, and a source electrode and a drain electrode disposed on the substrate to be spaced apart from each other with respect to the control gate electrode, wherein the control gate electrode includes a first metal material, wherein the first floating gate electrode includes a second metal material, wherein the second floating gate electrode includes a third metal material, wherein the first to third metal materials are different from each other, wherein an oxidizing power of the second metal material is smaller than an oxidizing power of the first metal material.

Methods and structures for fabricating a semiconductor device that includes a reduced programming current phase change memory (PCM) are provided. The method includes forming a bottom electrode. The method further includes forming a PCM and forming a conductive bridge filament in a dielectric to serve as a heater for the PCM. The method also includes forming a top electrode.

Some embodiments relate to a method for forming a memory device. The method includes forming a lower dielectric layer over a conductive wire. A stack of memory layers is formed within the lower dielectric layer and over the conductive wire. The stack of memory layers comprises a top electrode, a bottom electrode, and a data storage layer between the top electrode and the bottom electrode. A removal process is performed on the stack of memory layers to define a programmable metallization cell that comprises the top electrode, the bottom electrode, and the data storage layer. The programmable metallization cell comprises a central region and a peripheral region that extends upwardly from the central region. A top surface of the programmable metallization cell and a top surface of the lower dielectric layer are coplanar.

An antifuse circuit includes a current generator and an antifuse sense unit. The current generator has at least one electronic device. The antifuse sense unit is electrically connected to the current generator, and the antifuse sense unit has at least one copied electronic device. An electronic device specification of the at least one electronic device of the antifuse sense unit is equal to an electronic device specification of the at least one copied electronic device of the current generator. The current generator supplies a current to the antifuse sense unit that senses an antifuse.

An embodiment of the invention may include a memory structure. The memory structure may include a first terminal connected to a first contact. The memory structure may include a second terminal connected to a second contact and a third contact. The memory structure may include a multi-level nonvolatile electrochemical cell having a variable resistance channel and a programming gate. The memory structure may include the first contact and second contact connected to the variable resistance channel. The memory structure may include the third contact is connected to the programming gate. This may enable decoupled read-write operations of the device.

The present invention relates to a synapse and synaptic array, and a computing system using the same. The synaptic device according to an exemplary embodiment of the present invention includes a transistor in which a synaptic input signal is applied to any one electrode of source and drain electrodes; and a plurality of two-terminal variable resistance memory devices in which a first electrode is electrically globally connected to a gate electrode of the transistor, wherein a separate memory voltage is applied to a second electrode of each variable resistance memory device to adjust a gate voltage applied to the gate electrode, thereby controlling a synaptic output signal which is output to the other one of the source and drain electrodes.

Various embodiments of the present disclosure are directed towards a method for forming an integrated chip. The method includes forming a bottom electrode over a substrate. A data storage structure is formed on the bottom electrode. The data storage structure comprises a first dopant with a first atomic percent and a second dopant with a second atomic percent. The first atomic percent is different from the second atomic percent. A top electrode is formed on the data storage structure.

In some embodiments, a semiconductor device is provided. The semiconductor device includes a semiconductor substrate having a first semiconductor material layer separated from a second semiconductor material layer by an insulating layer. A first access transistor is arranged on the first semiconductor material layer, where the first access transistor has a pair of first source/drain regions having a first doping type. A second access transistor is arranged on the first semiconductor material layer, where the second access transistor has a pair of second source/drain regions having a second doping type opposite the first doping type. A resistive memory cell having a bottom electrode and an upper electrode is disposed over the semiconductor substrate, where one of the first source/drain regions and one of the second source/drain regions are electrically coupled to the bottom electrode.