Abstract: A semiconductor device structure is provided. The semiconductor device structure includes a channel structure and a gate stack wrapped around the channel structure. The semiconductor device structure also includes an epitaxial structure adjacent to the channel structure. The epitaxial structure includes a main portion and a lower portion below the main portion. A top of the channel structure is vertically between a top of the main portion and a bottom of the main portion, and the main portion and the lower portion are oppositely doped.

Abstract: A semiconductor device having a first epitaxial layer of a first doping type, a second epitaxial of a second doping type and a third epitaxial layer of the first doping type. A first trench and a second trench vertically extend from a first surface of the third epitaxial layer into the third epitaxial layer. A body region of the second doping type arranged in the third epitaxial layer. A body contact region of the second doping type surrounding the body region. A buried region of the second doping type connecting a portion of the body region between the first trench and the second trench to the body contact region.

Abstract: A semiconductor device includes a substrate including an N-type region and a P-type region, a first active pattern on the N-type region, a first gate structure on the N-type region, the first gate structure crossing the first active pattern and including fluorine (F), a second active pattern on the P-type region, and a second gate structure on the P-type region, the second gate structure crossing the second active pattern and including fluorine (F), where the first gate structure includes a first gate dielectric film on the first active pattern, and a first gate electrode on the first gate dielectric film, the second gate structure includes a second gate dielectric film on the second active pattern and a second gate electrode on the second gate dielectric film, and a fluorine (F) concentration of the second gate dielectric film is smaller than a fluorine (F) concentration of the first gate dielectric film.

Abstract: Provided is a semiconductor device which includes: a 1st source/drain pattern; a 2nd source/drain pattern; an isolation wall between the 1st source/drain pattern and the 2nd source/drain pattern; a 1st active contact on the 1st source/drain pattern; and a 2nd active contact on the 2nd source/drain pattern, wherein the 1st active contact contacts a 1st side surface of the isolation wall, and the 2nd active contact contacts a 2nd side surface of the isolation wall, opposite to the 1st sidewall.

Abstract: A shoe or other footwear has a non-removable multi-layer insole. A middle layer of the insole has apertures that define several discrete storage chambers within the insole. Each storage chamber stores a mixture of particulate or granular materials, such as sand, powdered titanium, powdered aluminum, powdered talcum, powdered zinc. The insole or footwear further includes integrated components such as: electromyogram (EMG) sensors, temperature sensors, pressure sensors, humidity sensors, sweat sensors. The insole or footwear further includes integrated stimulating units, such as: Transcutaneous Electrical Nerve Stimulation (TENS) units, electrodes, infrared radiation units. Data is sensed by the sensors integrated in the insole or footwear, in response to a human foot stepping on the discrete storage chambers that store the particulate or granular materials, and optionally in response to stimulation operations.

Abstract: A vibrating module and a makeup tool including the vibrating module are proposed. The vibrating module includes a vibration device detachably attached to a makeup tool and attached to the makeup tool to transfer vibration, and a handle component coupled with the vibration device, made in the form of a pair of folding wings, and configured to drive the vibration device when the first and second wings are folded and contact each other.

Abstract: An evaporator base pan assembly of an air-cooled display cabinet is provided. The evaporator base pan assembly includes an enclosure, an evaporator base pan, and a ventilation panel that are arranged sequentially from bottom to top, where an outer side of the evaporator base pan extends outward and bends downward to form a hook portion; the evaporator base pan is hooked to an upper end of the enclosure through the hook portion; a bottom portion of the ventilation panel abuts on an upper edge of the evaporator base pan; the bottom portion of the ventilation panel extends downward to form a limiting portion; and the limiting portion is located on an outer side of the hook portion.

Abstract: A split-type footrest includes a sucker, a shell and a foot-pedal. The shell is fixedly connected to the sucker. The shell is provided with at least one snapping part. The foot-pedal is correspondingly provided with a hanging arm, and the head of the hanging arm is provided with a lug. The lug is used to be inserted into the snapping part so as to form a detachable snap connection. There are snapping parts symmetrically provided on both sides of the shell respectively. There are two hanging arms and they are arranged on both sides of the foot-pedal respectively. Each hanging arm is provided with a lug, and each lug extends toward the other lug. The lugs are in one-to-one correspondence with the snapping parts. The foot-pedal and the main body can be disassembled for separate transportation.

Abstract: Tools used within a surgical area may be equipped with sensors that allow them to be tracked within the magnetic field of an image guided surgery (IGS) system. The IGS system may be configured to detect various movement patterns of the tools, which may be mapped to and associated with corresponding actions or inputs to the IGS system. In one example, a registration probe may be moved along the x-axis and y-axis, with detected movements identified and received by the IGS system as movements of a mouse cursor on a display of the IGS system. In another example, the registration probe may be moved in a circular pattern, or quickly moved along any of the x-axis, y-axis, or z-axis, with each being configured to cause the IGS system to zoom a display, change a view, record video, or other actions.