The present application discloses a method for making an active area air gap, comprising: step 1, performing word line etching to form a plurality of word line structures on a semiconductor substrate, wherein each word line structure spans each field oxide and each active area; step 2, forming a protective spacer on a side surface of the word line structure in a self-aligned manner; step 3, etching the field oxide by means of isotropic etching, so as to lower the top surfaces of the field oxides within and outside a coverage area of the word line structure and thus form an active area air gap between the active areas, wherein the word line structure spans the active area air gap; and step 4, removing the protective spacer.

The present application discloses a method for making an active area air gap, comprising: step 1, performing word line etching to form a plurality of word line structures on a semiconductor substrate, wherein each word line structure spans each field oxide and each active area; step 2, forming a protective spacer on a side surface of the word line structure in a self-aligned manner; step 3, etching the field oxide by means of isotropic etching, so as to lower the top surfaces of the field oxides within and outside a coverage area of the word line structure and thus form an active area air gap between the active areas, wherein the word line structure spans the active area air gap; and step 4, removing the protective spacer.

Various examples of memory systems comprising an address fault detection system are disclosed. The memory system comprises a first memory array, a row decoder, and an address fault detection system comprising a second array, wherein the row decoder decodes row addresses into word lines, each word line coupled to a row of cells in the first array and a row of cells in the second array. The second array contains digital bits and/or analog values that are used to identify address faults.

The present disclosure, in some embodiments, relates to an integrated chip. The integrated chip includes a source/drain region arranged within a substrate. A first select gate is arranged over the substrate, and a first memory gate is arranged over the substrate and separated from the source/drain region by the first select gate. An inter-gate dielectric structure is arranged between the first memory gate and the first select gate. The inter-gate dielectric structure extends under the first memory gate. A height of the inter-gate dielectric structure decreases along a direction extending from the first select gate to the first memory gate.

Various embodiments of the present application are directed towards an integrated memory chip comprising a memory array with a strap-cell architecture that reduces the number of distinct strap-cell types and that reduces strap-line density. In some embodiments, the memory array is limited to three distinct types of strap cells: a source line/erase gate (SLEG) strap cell; a control gate/word line (CGWL) strap cell; and a word-line strap cell. The small number of distinct strap-cell types simplifies design of the memory array and further simplifies design of a corresponding interconnect structure. Further, in some embodiments, the three distinct strap-cell types electrically couple word lines, erase gates, and control gates to corresponding strap lines in different metallization layers of an interconnect structure. By spreading the strap lines amongst different metallization layers, strap-line density is reduced.

Various embodiments of the present application are directed towards an integrated memory chip comprising a memory array with a strap-cell architecture that reduces the number of distinct strap-cell types and that reduces strap-line density. In some embodiments, the memory array is limited to three distinct types of strap cells: a source line/erase gate (SLEG) strap cell; a control gate/word line (CGWL) strap cell; and a word-line strap cell. The small number of distinct strap-cell types simplifies design of the memory array and further simplifies design of a corresponding interconnect structure. Further, in some embodiments, the three distinct strap-cell types electrically couple word lines, erase gates, and control gates to corresponding strap lines in different metallization layers of an interconnect structure. By spreading the strap lines amongst different metallization layers, strap-line density is reduced.

A floating-node memory device includes a metal-oxide-semiconductor (MOS) transistor including a first polysilicon gate, a source region, and a drain region in a first well region, a tunneling device including a second polysilicon gate in a second well region, and a metal-insulator-metal (MIM) capacitor including a conductive top plate and a bottom plate formed in a metal interconnect layer. The floating-node device includes a floating-node comprising the first polysilicon gate, the second polysilicon gate, and the conductive top plate of the MIM capacitor coupled together, a control node at the bottom plate of the MIM capacitor, an erase node in the second well region, a source node at the source region of the MOS transistor, and a drain node at the drain region of the MOS transistor.

An embodiment memory device includes a drain electrode disposed on a semiconductor substrate, a channel region in contact with the drain electrode, a source electrode in contact with the channel region, and a floating gate region in contact with the source electrode and the drain electrode, the floating gate region including a nano-dot region including at least one nano-dot gate, wherein the drain electrode is overlapped with the nano-dot region, and wherein the nano-dot region is overlapped with the channel region.

An embodiment memory device includes a drain electrode disposed on a semiconductor substrate, a channel region in contact with the drain electrode, a source electrode in contact with the channel region, and a floating gate region in contact with the source electrode and the drain electrode, the floating gate region including a nano-dot region including at least one nano-dot gate, wherein the drain electrode is overlapped with the nano-dot region, and wherein the nano-dot region is overlapped with the channel region.

A non-volatile memory device includes a floating-node memory cell disposed in an integrated circuit (IC). The memory cell includes a floating-node, a control node, an erase node, a source node, and a drain node. The memory device also includes a high-voltage input node for coupling to an external programmable high-voltage source external to the IC. The memory device also includes a high-voltage switch circuit coupled to the high-voltage input node for providing a voltage signal for performing hot-electron programming of charges to the floating node and tunneling erase of charges from the floating node.