In a semiconductor device, a memory cell is formed of a control gate electrode and a memory gate electrode adjacent to each other, a gate insulating film formed below the control gate electrode and an insulating film formed below the memory gate electrode and having a charge accumulating part therein. Also, in this semiconductor device, a capacitive element is formed of a lower electrode, an upper electrode and a capacitive insulating film formed between the upper electrode and the lower electrode. A thickness of the lower electrode is smaller than a thickness of the control gate electrode.

An integrated circuit includes a ferroelectric memory cell. The ferroelectric memory cell includes a ferroelectric layer stack comprising at least one ferroelectric material oxide layer. Each of the ferroelectric material oxide layers includes a ferroelectric material that is at least partially in a ferroelectric state. The ferroelectric layer stack comprises at least two ferroelectric domains. Further, the voltage which is to applied to the layer stack to induce polarization reversal differs for the individual domains such that polarization reversal of individual domains or of a portion of the totality of ferroelectric domains within the ferroelectric material of can be attained.

A method of making a capacitor with reduced variance comprises providing a bottom plate in a first metal layer, a first dielectric material over the bottom plate, and a middle plate in a second metal layer to form a first capacitor. The method also comprises measuring the capacitance of the first capacitor, and determining whether to couple none, one, or both of a second capacitor and a third capacitor in parallel with the first capacitor. The method may further comprise the steps of providing a second dielectric material over the middle plate, and providing a first top plate and a second top plate in a third metal layer to form the second capacitor, and a third capacitor. Electrical connections may be formed to couple one or both of the second capacitor and the third capacitor in parallel with the first capacitor based on the measured value of the first capacitor.

A method of forming an IC includes providing a field dielectric in a portion of a semiconductor surface, a bipolar or Schottky diode (BSD) class device area, a CMOS transistor area, and a resistor area. A polysilicon layer is deposited to provide a polysilicon gate area for MOS transistors in the CMOS transistor area, over the BSD class device area, and over the field dielectric for providing a polysilicon resistor in the resistor area. A first mask pattern is formed on the polysilicon layer. Using the first mask pattern, first implanting (I.sub.1) of the polysilicon resistor providing a first projected range (R.sub.P1)<a thickness of the polysilicon layer and second implanting (I.sub.2) providing a second R.sub.P(R.sub.P2), where R.sub.P2>R.sub.P1. I.sub.2 provides a CMOS implant into the semiconductor surface layer in the CMOS transistor area and/or a BSD implant into the semiconductor surface layer in the BSD area.

A system and method for manufacturing a semiconductor device is provided. An embodiment comprises forming a deposited layer using an atomic layer deposition (ALD) process. The ALD process may utilize a first precursor for a first time period, a first purge for a second time period longer than the first time period, a second precursor for a third time period longer than the first time period, and a second purge for a fourth time period longer than the third time period.

Some embodiments include apparatuses and methods having a node to receive ground potential, a first diode including an anode coupled to the node, a second diode including an anode coupled to the node, a first circuit to apply a voltage to a cathode of each of the first and second diodes to cause the first and second diodes to be in a forward-bias condition, and a second circuit to generate a signal having a duty cycle based on a first voltage across the first diode and a second voltage across the second diode. At least one of such the embodiments includes a temperature calculator to calculate a value of temperature based at least in part on the duty cycle of the signal.

A method of forming a semiconductor structure, comprising forming a dual damascene structure having a capacitor trench and an interconnect trench, forming a first electrode a dielectric of the capacitor, and, depositing a metal within said capacitor trench and said interconnection trench wherein the metal forms a second electrode of the capacitor and also forms an interconnection between layers of an interconnecting structure of a semiconductor device. A semiconductor structure, comprising a dual damascene structure having a capacitor trench for a capacitor, the capacitor including a first electrode, a second electrode, and a high-K dielectric between the first and second electrodes, the high-k dielectric configured to seal the first electrode from the second electrode and from subsequent wiring layers of the interconnecting structure of the semiconductor device, and, an interconnection trench for a metal interconnection to form an interconnection between the interconnecting structure of the semiconductor device.

The present disclosure provides a chip part. The chip part includes a substrate, a capacitor portion and a substrate body portion. The capacitor portion includes a plurality of wall portions having a lengthwise direction and separated from each other by a trench formed on a first main surface of the substrate. The substrate body portion is formed around the capacitor portion using a portion of the substrate. The plurality of wall portions are formed of a plurality of pillar units. The capacitor portion, in the plan view, includes a first capacitor portion and a second capacitor portion. The first capacitor portion includes the plurality of wall portions having the lengthwise direction as a first lengthwise direction. The second capacitor portion includes the plurality of wall portions having the lengthwise direction as a second lengthwise direction orthogonal to the first lengthwise direction.

A package includes a first die, a second die, and an encapsulant. The first die includes a first capacitor. The second die includes a second capacitor. The second die is stacked on the first die. The first capacitor is spatially separated from the second capacitor. The first capacitor is electrically connected to the second capacitor. The encapsulant laterally encapsulates the second die.

Disclosed herein are via plug resistors for incorporation into electronic substrates, and related methods and devices. Exemplary via plug resistor structures include a resistive element within and on a surface of a via extending at least partially through an electronic substrate and first and second electrodes coupled to the resistive element.