A method of forming a device on a substrate with recessed first/third areas relative to a second area by forming a fin in the second area, forming first source/drain regions (with first channel region therebetween) by first/second implantations, forming second source/drain regions in the third area (defining second channel region therebetween) by the second implantation, forming third source/drain regions in the fin (defining third channel region therebetween) by third implantation, forming a floating gate over a first portion of the first channel region by first polysilicon deposition, forming a control gate over the floating gate by second polysilicon deposition, forming an erase gate over the first source region and a device gate over the second channel region by third polysilicon deposition, and forming a word line gate over a second portion of the first channel region and a logic gate over the third channel region by metal deposition.

A method of forming a device with a silicon substrate having upwardly extending first and second fins. A first implantation forms a first source region in the first silicon fin. A second implantation forms a first drain region in the first silicon fin, and second source and drain regions in the second silicon fin. A first channel region extends between the first source and drain regions. A second channel region extends between the second source and drain regions. A first polysilicon deposition is used to form a floating gate that wraps around a first portion of the first channel region. A second polysilicon deposition is used to form an erase gate wrapping around first source region, a word line gate wrapping around a second portion of the first channel region, and a dummy gate wrapping around the second channel region. The dummy gate is replaced with a metal gate.

A capacitive element of an integrated circuit includes first and second electrodes. The first electrode is formed by a first electrically conductive layer located above a semiconductor well doped with a first conductivity type. The second electrode is formed by a second electrically conductive layer located above the first electrically conductive layer of the semiconductor well. The second electrode is further formed by a doped surface region within the semiconductor well that is heavily doped with a second conductivity type opposite the first conductivity type, wherein the doped surface region is located under the first electrically conductive layer. An inter-electrode dielectric area electrically separates the first electrode and the second electrode.

An EEPROM includes a floating gate transistor having a source region, a channel region and a drain region. A first capa implant zone on a drain-side of the floating gate transistor has a first dopant concentration level. A second capa implant zone in the first capa implant zone adjacent the drain region has a second dopant concentration level that is greater than the first dopant concentration level. A gate oxide region insulates the floating gate electrode from the channel region, first capa implant zone and second capa implant zone. A thickness of the gate oxide region is thinner at the second capa implant zone than at the channel region and first capa implant zone.

A method for manufacturing a memory device is provided. The method includes the following steps: providing a substrate; forming a plurality of first gate structures; forming a lining layer on the substrate; forming a spacer layer on the lining layer; forming a stop layer on the spacer layer; forming a first sacrificial layer on the stop layer; removing a portion of the first sacrificial layer to expose the stop layer on the first gate structures, and to expose the stop layer at the bottoms of the trenches; removing the stop layer at the bottoms of the trenches to expose the spacer layer; removing the remaining first sacrificial layer; forming a second sacrificial layer on the substrate; and removing the second sacrificial layer, and removing the spacer layer and the lining layer at the bottoms of the plurality of trenches to expose the substrate.

Described herein is an apparatus comprising a plurality of silicon-containing layers wherein the silicon-containing layers are selected from a silicon oxide and a silicon nitride layer or film. Also described herein are methods for forming the apparatus to be used, for example, as 3D vertical NAND flash memory stacks. In one particular aspect or the apparatus, the silicon oxide layer comprises slightly compressive stress and good thermal stability. In this or other aspects of the apparatus, the silicon nitride layer comprises slightly tensile stress and less than 300 MPa stress change after up to about 800° C. thermal treatment. In this or other aspects of the apparatus, the silicon nitride layer etches much faster than the silicon oxide layer in hot H.sub.3PO.sub.4, showing good etch selectivity.

A semiconductor device is provided in which the power consumption can be reduced by reducing the driving voltage and the on-state current can be increased in a period in which a transistor having an extremely low off-state current is brought into an electrically floating state. The semiconductor device comprises a memory cell, a first circuit, and a second circuit. The memory cell includes a first transistor. The first transistor includes a first semiconductor layer, a first gate electrode, and a first back gate electrode. The first gate electrode is connected to a word line. The first back gate electrode is connected to a back gate line. The first circuit supplies a signal for controlling the conduction state of the first transistor to the word line. The second circuit supplies a voltage for controlling the threshold voltage of the first transistor to the back gate line. The second circuit has a function of bringing the back gate line into an electrically floating state in a period in which a signal for controlling the conduction state of the first transistor is supplied to the word line.

This invention is to improve a performance of a semiconductor device. The semiconductor device includes a semiconductor substrate, a p-type well region formed in the semiconductor substrate, a first insulating layer formed over the p-type well region, a semiconductor layer formed over the first insulating layer, a second insulating layer formed over the semiconductor layer, and a conductor layer formed over the second insulating layer. A first capacitive element is comprised of the semiconductor layer, the second insulating layer, and the conductor layer, while a second capacitive element is comprised of the p-type well region, the first insulating layer, and the semiconductor layer, in which each of the semiconductor substrate and the semiconductor layer includes a single crystal silicon layer.

A field-programmable-gate-array (FPGA) IC chip includes multiple first non-volatile memory cells in the FPGA IC chip, wherein the first non-volatile memory cells are configured to save multiple resulting values for a look-up table (LUT) of a programmable logic block of the FPGA IC chip, wherein the programmable logic block is configured to select, in accordance with its inputs, one from the resulting values into its output; and multiple second non-volatile memory cells in the FPGA IC chip, wherein the second non-volatile memory cells are configured to save multiple programming codes configured to control a switch of the FPGA IC chip.

A capacitive element of an integrated circuit includes first and second electrodes. The first electrode is formed by a first electrically conductive layer located above a semiconductor well doped with a first conductivity type. The second electrode is formed by a second electrically conductive layer located above the first electrically conductive layer of the semiconductor well. The second electrode is further formed by a doped surface region within the semiconductor well that is heavily doped with a second conductivity type opposite the first conductivity type, wherein the doped surface region is located under the first electrically conductive layer. An inter-electrode dielectric area electrically separates the first electrode and the second electrode.