Techniques that can facilitate high-transparency semiconductor-metal interfaces are provided. In one example, a method can comprise forming a silicon on insulator (SOI) over a wafer. The method can further comprise depositing a metal on the SOI. The method can further comprise forming a structure by dry-etching the metal and dry-etching the SOI. The method can further comprise forming a template over the structure. The method can further comprise etching a portion of the SOI for removal under the metal. The method can further comprise growing a semiconductor where the portion of SOI was removed.

A semiconductor device is provided. The semiconductor device includes a template layer disposed over a substrate and having a trench therein, a buffer structure disposed over a bottom surface of the trench and comprising a metal oxide, a single crystal semiconductor structure disposed within the trench and over the buffer structure and a gate structure disposed over a channel region of the single crystal semiconductor structure.

Embodiments of the present disclosure may generally relate to systems, apparatus, and/or processes to form volumes of oxide within a fin, such as a Si fin. In embodiments, this may be accomplished by applying a catalytic oxidant material on a side of a fin and then annealing to form a volume of oxide. In embodiments, this may be accomplished by using a plasma implant technique or a beam-line implant technique to introduce oxygen ions into an area of the fin and then annealing to form a volume of oxide. Processes described here may be used manufacture a transistor, a stacked transistor, or a three-dimensional (3-D) monolithic stacked transistor.

Disclosed is a three-dimensional semiconductor device including a horizontal semiconductor layer including a plurality of well regions having a first conductivity and a separation impurity region having a second conductivity, and a plurality of cell array structures provided on the well regions of the horizontal semiconductor layer, respectively. The separation impurity region is between and in contact with the well regions. Each of the cell array structures comprises a stack structure including a plurality of stacked electrodes in a vertical direction to a top surface of the horizontal semiconductor layer, and a plurality of vertical structures penetrating the stack structure and connected to a corresponding well region.

The present disclosure relates to semiconductor structures and, more particularly, to a transistor with an embedded isolation layer in a bulk substrate and methods of manufacture. The structure includes: a bulk substrate; an isolation layer embedded within the bulk substrate and below a top surface of the bulk substrate; a deep trench isolation structure extending through the bulk substrate and contacting the embedded isolation layer; and a gate structure over the top surface of the bulk substrate and vertically spaced away from the embedded isolation layer, the deep trench isolation structure and the embedded isolation layer defining an active area of the gate structure in the bulk substrate.

A method for treating a wafer is provided with a portion of a semiconductor layer is selectively removed from the wafer so as to create an inactive region of the wafer surrounding a first active region of the wafer. The inactive region of the wafer has an exposed portion of an insulator layer, but none of the semiconductor layer. The first active region of the wafer includes a first portion of the semiconductor layer and a first portion of the insulator layer. At least one conductor is formed in contact with the first portion of the semiconductor layer, such that the conductor and the first portion of the semiconductor layer form a portion of an electrical circuit. The first active region of the wafer is selectively treated to remove a native oxide layer from the first portion of the semiconductor layer. A resulting wafer is also disclosed.

Apparatus and methods relating to heterolithic microwave integrated circuits HMICs are described. An HMIC can include different semiconductor devices formed from different semiconductor systems in different regions of a same substrate. An HMIC can also include bulk regions of low-loss electrically-insulating material extending through the substrate and located between the different semiconductor regions. Passive RF circuit elements can be formed on the low-loss electrically-insulating material.

A semiconductor device includes at least one active pattern on a substrate, at least one gate electrode intersecting the at least one active pattern, source/drain regions on the at least one active pattern, the source/drain regions being on opposite sides of the at least one gate electrode, and a barrier layer between at least one of the source/drain regions and the at least one active pattern, the barrier layer being at least on bottoms of the source/drain regions and including oxygen.

In radio-frequency (RF) devices integrated on semiconductor-on-insulator (e.g., silicon-based) substrates, RF losses may be reduced by increasing the resistivity of the semiconductor device layer in the vicinity of (e.g., underneath and/or in whole or in part surrounding) the metallization structures of the RF device, such as, e.g., transmission lines, contacts, or bonding pads. Increased resistivity can be achieved, e.g., by ion-implantation, or by patterning the device layer to create disconnected semiconductor islands.

A testing method and apparatus is disclosed for testing an integrated circuit device (100) which has a dedicated ground bias pad (121) connected across a high voltage electrostatic discharge clamp circuit (123) to a well-driving ground pad (122) by applying a first voltage to the dedicated ground bias pad to bias a wafer substrate (101) while simultaneously applying a second voltage to the well-driving ground pad to bias the well region (103), where the first and second voltage create a stressing voltage across a buried insulator layer (102, 105) in the integrated circuit device so that a screening test can be conducted to screen for a defect (106) in the buried insulator layer by measuring a leakage current.