Provided is an optical module comprising a plate-like metal stem and a semiconductor optical modulation element mounted to a dielectric substrate provided on one side of the metal stem, wherein the metal stem has a metal stem penetration section in which a metal lead pin is inserted coaxially in a penetration hole which is formed in the metal stem and a dielectric member is provided to fill the penetration hole around the outer circumference of the lead pin, and a signal for modulation is supplied to the semiconductor optical modulation element connected in parallel with a terminal matching circuit, from the other side of the metal stem via the metal stem penetration section, wherein the terminal matching circuit is configured by a series connecting body which is comprised of a first resistor and a parallel body which is comprised of a second resistor and a capacitor.

An integrated circuit includes a resistive material layer formed on a substrate, a metal layer formed on the resistive material layer, a bipolar transistor formed on the substrate, and a resistive element formed on the substrate. The bipolar transistor includes, as a sub-layer, the metal layer formed in a first region, and also includes a collector layer formed on the sub-collector layer. The resistive element is constituted by the resistive material layer formed in a second region.

The present disclosure is directed to a flat no-lead semiconductor package with a surfaced mounted structure. An end portion of the surface mounted structure includes a recessed member so that the surface mounted structure is coupled to leads of the flat no-lead semiconductor package through, among others, the sidewalls of the recessed members.

An integrated circuit package is disclosed. The integrated circuit package includes a first integrated circuit die, a second integrated circuit die, an organic substrate, wherein both the first integrated circuit die and the second integrated circuit die are connected to the organic substrate, a multi-die interconnect bridge (EMIB) embedded within the organic substrate, and a termination resistor associated with a circuit in the first integrated circuit die, wherein the termination resistor is located within the multi-die interconnect bridge embedded within the organic substrate.

A semiconductor device is disclosed. In one example, the semiconductor device includes: an electronic component having a top surface, a bottom surface, and two end portions; a plurality of contacts disposed on the top surface; and a plurality of metal nodes disposed on the plurality of contacts. The plurality of contacts includes two end contacts disposed at the two end portions respectively and at least one intermediate contact disposed between the two end contacts. The plurality of metal nodes includes two end metal nodes disposed on the two end contacts respectively and at least one intermediate metal node disposed on the at least one intermediate contact.

Methods of depositing a silicon oxide film are disclosed. One embodiment is a plasma enhanced atomic layer deposition (PEALD) process that includes supplying a vapor phase silicon precursor, such as a diaminosilane compound, to a substrate, and supplying oxygen plasma to the substrate. Another embodiment is a pulsed hybrid method between atomic layer deposition (ALD) and chemical vapor deposition (CVD). In the other embodiment, a vapor phase silicon precursor, such as a diaminosilane compound, is supplied to a substrate while ozone gas is continuously or discontinuously supplied to the substrate.

A semiconductor substrate has a front face and a back face. A first contact and a second contact, spaced apart from each other, are located on the front face. An electrically conductive wafer is located on the back face. A detection circuit is configured to detect a thinning of the substrate from the back face. The detection circuit including a measurement circuit that takes a measurement of a resistive value of the substrate between said at least one first contact, said at least one second contact and said electrically conductive wafer. Thinning is detected in response to the measured resistive value.

In various embodiments, a passive electronic component is disclosed. The passive electronic component can have a first surface and a second surface opposite the first surface. The passive electronic component can include a nonconductive material and a capacitor embedded within the nonconductive material. The capacitor can have a first electrode, a second electrode, and a dielectric material disposed between the first and second electrodes. The first electrode can comprise a first conductive layer and a plurality of conductive fibers extending from and electrically connected to the first conductive layer. A first conductive via can extend through the passive electronic component from the first surface to the second surface, with the first conductive via electrically connected to the first electrode.

A semiconductor module is obtained in which breakage of the semiconductor module can be detected in advance while suppressing increase in manufacturing cost. A semiconductor module includes a semiconductor element, a circuit board, a resistor, a first wiring member, and a detector. The circuit board includes a circuit pattern. The resistor is connected to a surface of the circuit pattern. The first wiring member directly connects the resistor to the semiconductor element. In the first wiring member, at least part of current flowing from the semiconductor element to the circuit pattern flows. The detector is configured to detect at least one of a change of a voltage drop value in the resistor and a change of a current value in the resistor.

A first conductive routing structure is electrically connected to a first electronic component. A second conductive routing structure is electrically connected to a second electronic component. An additive deposition process deposits a material over a surface of a processed wafer to form a conductive or resistive structure, which extends from a portion of the first conductive routing structure to a portion of the second conductive routing structure, to configure a circuit including the first and second electronic components.