The present disclosure generally relates to memory devices and methods of forming the same. More particularly, the present disclosure relates to resistive random-access (ReRAM) memory devices. The present disclosure provides a memory device including an opening in a dielectric structure, the opening having a sidewall, a first electrode on the sidewall of the opening, a spacer layer on the first electrode, a resistive layer on the first electrode and upon an upper surface of the spacer layer, and a second electrode on the resistive layer.

Some embodiments relate to a memory device. The memory device includes a bottom electrode overlying a substrate. A data storage layer overlies the bottom electrode. A top electrode overlies the data storage layer. A conductive bridge is selectively formable within the data storage layer to couple the bottom electrode to the top electrode. A diffusion barrier layer is disposed between the data storage layer and the top electrode.

Some embodiments relate to a method for forming an integrated chip. The method includes forming a bottom electrode over a substrate. A data storage layer is formed on the bottom electrode. A diffusion barrier layer is formed over the data storage layer. The diffusion barrier layer has a first diffusion activation temperature. A top electrode is formed over the diffusion barrier layer. The top electrode has a second diffusion activation temperature less than the first diffusion activation temperature.

The present invention provides a multi-layer selector device exhibiting a low leakage current by controlling a threshold voltage. According to an embodiment of the present invention, the multi-layer selector device comprises: a substrate; a lower electrode layer disposed on the substrate; an insulating layer disposed on the lower electrode layer and having a via hole passing through to expose the lower electrode layer; a switching layer disposed on the lower electrode layer in the via hole, performing a switching operation by forming and destroying a conductive filament, and made of a multi-layer to control the formation of the conductive filament; and an upper electrode layer disposed on the switching layer.

An IC structure comprises a substrate, a first material layer, a second material layer, a first via structure, and a memory cell structure. The substrate comprises a memory region and a logic region. The first material layer is disposed on the memory region and the logic region. The second material layer is disposed on the first material layer only at the memory region. The first via structure formed in the first material layer and the second material layer. The memory cell structure is over the first via structure.

A three-dimensional semiconductor integrated circuit includes a first CMOS circuit layer including a plurality of first CMOS circuit blocks; an insulating layer disposed on a top of the first CMOS circuit layer; a plurality of atomic switching elements respectively disposed inside via holes extending through the insulating layer, wherein the plurality of atomic switching elements are electrically connected to the plurality of first CMOS circuit blocks, respectively; a driver circuit layer disposed on a top of the insulating layer, and electrically connected with the atomic switching elements, wherein the driver circuit layer include a driver circuit for selectively turning on and off the atomic switching elements; and a second CMOS circuit disposed on a top of the driver circuit layer and connected to the atomic switching elements.

A ferroelectric component includes a first electrode, a tunnel barrier layer disposed on the first electrode to include a ferroelectric material, a tunneling control layer disposed on the tunnel barrier layer to control a tunneling width of electric charges passing through the tunnel barrier layer, and a second electrode disposed on the tunneling control layer.

A memory device according to an embodiment includes a first interconnect, a second interconnect, a first variable resistance member, a third interconnect, a second variable resistance member, a fourth interconnect, a fifth interconnect and a third variable resistance member. The first interconnect, the third interconnect and the fourth interconnect extend in a first direction. The second interconnect and the fifth interconnect extend in a second direction crossing the first direction. The first variable resistance member is connected between the first interconnect and the second interconnect. The second variable resistance member is connected between the second interconnect and the third interconnect. The third variable resistance member is connected between the fourth interconnect and the fifth interconnect. The fourth interconnect is insulated from the third interconnect.

Some embodiments relate to a memory device. The memory device includes a first electrode overlying a substrate. A data storage layer is disposed on the first electrode. A second electrode overlies the data storage layer. A buffer layer is disposed between the data storage layer and the second electrode.

Technology for reading reversible resistivity cells in a memory array when using a current-force read is disclosed. The memory cells are first read using a current-force referenced read. If the current-force referenced read is successful, then results of the current-force referenced read are returned. If the current-force referenced read is unsuccessful, then a current-force self-referenced read (SRR) is performed and results of the current-force SRR are returned. The current-force referenced read provides a very fast read of the memory cells and can be successful in most cases. The current-force SRR provides a more accurate read in the event that the current-force referenced read is not successful. Moreover, the current-force referenced read may use less power than the current-force SRR. In an aspect this mixed current-force read is used for MRAM cells, which are especially challenging to read.