In a semiconductor device including a split gate type MONOS memory, and a trench capacitor element having an upper electrode partially embedded in trenches formed in the main surface of a semiconductor substrate, merged therein, the flatness of the top surface of the upper electrode embedded in the trench is improved. The polysilicon film formed over the semiconductor substrate to form a control gate electrode forming a memory cell of the MONOS memory is embedded in the trenches formed in the main surface of the semiconductor substrate in a capacitor element formation region, thereby to form the upper electrode including the polysilicon film in the trenches.

Dual gate FD-SOI transistors are used as MOSFET capacitors to replace passive well capacitors in analog microcircuits. Use of the dual gate FD-SOI devices helps to reduce unstable oscillations and improve circuit performance. A thick buried oxide layer within the substrate of an FD-SOI transistor forms a capacitive dielectric that can sustain high operating voltages in the range of 1.2 V-3.3 V, above the transistor threshold voltage. A secondary gate in the FD-SOI transistor is used to create a channel from the back side so that even when the bias voltage on the first gate is small, the effective capacitance remains higher. The capacitance of the buried oxide layer is further utilized as a decoupling capacitor between supply and ground. In one example, a dual gate PMOS FD-SOI transistor is coupled to an operational amplifier and a high voltage output driver to produce a precision-controlled voltage reference generator. In another example, two dual gate PMOS and one dual gate NMOS FD-SOI transistor are coupled to a charge pump, a phase frequency detector, and a current-controlled oscillator to produce a high-performance phase locked loop circuit in which the decoupling capacitor footprint is smaller, in comparison to the conventional usage of passive well capacitance.

The invention relates to a capacitor structure (2) comprising a silicon substrate (4) with first and second sides (6, 8), a double double Metal Insulator Metal trench capacitor (10) including a basis electrode (12), an insulator layer (16, 20), a second and a third conductive layers (18, 22); and comprising a second pad (26) and a fourth pad (30) coupled to the basis electrode (12), a first pad (24) and a third pad (28) coupled together, the first pad (24) being located on the same substrate side than the second pad (26), the third pad (28) being located on the same substrate side than the fourth pad (30), the third pad (28) being coupled to the second conductive layer (18), said second conductive layer (18) being flush with or protruding from the opposite second side (8).

Aspects of the present disclosure describe MOSFET devices that have snubber circuits. The snubber circuits comprise one or more resistors with a dynamically controllable resistance that is controlled by changes to a gate and/or drain potentials of the one or more MOSFET structures during switching events.

Macro-transistor structures are disclosed. In some cases, the macro-transistor structures have the same number of terminals and properties similar to long-channel transistors, but are suitable for analog circuits in deep-submicron technologies at deep-submicron process nodes. The macro-transistor structures can be implemented, for instance, with a plurality of transistors constructed and arranged in series, and with their gates tied together, generally referred to herein as a transistor stack. One or more of the serial transistors within the stack can be implemented with a plurality of parallel transistors and/or can have a threshold voltage that is different from the threshold voltages of other transistors in the stack. Alternatively, or in addition, one or more of the serial transistors within the macro-transistor can be statically or dynamically controlled to tune the performance characteristics of the macro-transistor. The macro-transistors can be used in numerous circuits, such as varactors, VCOs, PLLs, and tunable circuits.

In a semiconductor device including a split gate type MONOS memory, and a trench capacitor element having an upper electrode partially embedded in trenches formed in the main surface of a semiconductor substrate, merged therein, the flatness of the top surface of the upper electrode embedded in the trench is improved. The polysilicon film formed over the semiconductor substrate to form a control gate electrode forming a memory cell of the MONOS memory is embedded in the trenches formed in the main surface of the semiconductor substrate in a capacitor element formation region, thereby to form the upper electrode including the polysilicon film in the trenches.

A semiconductor device includes a substrate, an active layer, a transistor, and a capacitor. The active layer is disposed on the substrate, and the active layer is divided into a first portion and a second portion. The transistor and the capacitor are disposed on the substrate. The transistor includes the second portion, a source electrode, a drain electrode, and a gate electrode. The source electrode and the drain electrode are respectively and electrically connected to the second portion. The gate electrode is disposed on the second portion. The capacitor includes the first portion, a first electrode, a first insulating layer, and a second electrode. The first electrode is electrically connected to the first portion and the source electrode. The first insulating layer is disposed on the first portion. The second electrode is disposed on the first insulating layer and is electrically connected to the gate electrode.

A method for fabricating a multi-layer, crown-shaped MIM capacitor is provided. A base having therein a conductive region within a capacitor-forming region is formed. An IMD layer is deposited on the base to cover the capacitor-forming region. A capacitor trench is formed within the capacitor-forming region. The capacitor trench penetrates through the IMD layer, thereby exposing a portion of the conductive region. A concentric capacitor lower electrode structure is formed within the capacitor trench. The concentric capacitor lower electrode structure includes a first electrode and a second electrode surrounded by the first electrode. The first electrode is in direct contact with the conductive region. A conductive supporting pedestal is formed within the capacitor trench for fixing and electrically connecting bottom portions of the first and second electrodes. A capacitor dielectric layer conformally lining the first and second electrodes and a top surface of the conductive supporting pedestal is formed.

A method including forming an oxygen gettering layer on one side of an insulating layer of a deep trench capacitor between the insulating layer and a substrate, the oxygen gettering layer including an aluminum containing compound, and depositing an inner electrode on top of the insulating layer, the inner electrode including a metal.

Trench capacitors can be formed between lengthwise sidewalls of semiconductor fins, and source and drain regions of access transistors are formed in the semiconductor fins. A dummy gate structure is formed between end walls of a neighboring pair of semiconductor fins, and limits the lateral extent of raised source and drain regions that are formed by selective epitaxy. The dummy gate structure prevents electrical shorts between neighboring semiconductor fins. Gate spacers can be formed around gate structures and the dummy gate structures. The dummy gate structures can be replaced with dummy replacement gate structures or dielectric material portions, or can remain the same without substitution of any material. The dummy gate structures may consist of at least one dielectric material, or may include electrically floating conductive material portions.