Disclosed are a high-entropy carbide ceramic material and a preparation method thereof, and also a ceramic coating and its preparation method and use. The high-entropy carbide ceramic material has a chemical composition of (ZrCrTiVNb)C and includes Zr, Cr, Ti, V, and Nb, with a same mole fraction of 6-10%.

A film forming device includes a drum having a circumferential surface, a cathode accommodation unit disposed to be opposite to the circumferential surface, a first gas introducing unit which introduces a first gas into the cathode accommodation unit, and a second gas introducing unit which introduces a second gas between the circumferential surface and the cathode accommodation unit.

A sputtering apparatus includes a substrate holder, a first counterpart target area, a second counterpart target area, and a power supply. The first counterpart target area includes a first target and at least one first magnetic part and operates to form a magnetic field in a first plasma area adjacent to the first target. The second counterpart target area includes a second target and at least one second magnetic part and operates to form a magnetic field in a second plasma area adjacent to the second target. The power supply supplies a first power voltage to the first and second targets. A control anode faces the substrate holder in a second direction, with the first and second plasma areas therebetween, and receives a control voltage greater than the first power voltage.

An exemplary embodiment provides a thin film transistor array panel, including: a substrate; an oxide semiconductor layer disposed on the substrate; an insulating layer disposed on the oxide semiconductor layer; and a pixel electrode disposed on the insulating layer. The oxide semiconductor layer includes a first layer and a second layer disposed on the first layer, the second layer includes an oxide semiconductor including silicon, and the second layer contacts the insulating layer.

The semiconductor device includes a first insulator over a substrate, a first oxide semiconductor over the first insulator, a second oxide semiconductor over the first oxide semiconductor, a first conductor and a second conductor in contact with the second oxide semiconductor, a third oxide semiconductor on the second oxide semiconductor and the first and second conductors, a second insulator over the third oxide semiconductor, and a third conductor over the second insulator. At least one of the first oxide semiconductor, the second oxide semiconductor, and the third oxide semiconductor has a crystallinity peak that corresponds to a (hkl) plane (h=0, k=0, l is a natural number) observed by X-ray diffraction using a Cu K-alpha radiation as a radiation source. The peak appears at a diffraction angle 2 theta greater than or equal to 31.3 degrees and less than 33.5 degrees.

A sputtering apparatus includes: a processing container; a first target provided inside the processing container and formed of a first material; a second target provided inside the processing container and formed of a second material different from the first material; a stage provided inside the processing container to place a substrate thereon; a shielding plate arranged between the first target and the second target; and a controller, wherein the controller is configured to perform a process of reducing a film stress of a film formed on the shielding plate.

A deposition system, and a method of operation thereof are disclosed. The deposition system comprises a cathode assembly comprising a rotating magnet assembly including a plurality of outer peripheral magnets surrounding an inner peripheral magnet.

A method of fabricating a thin film with a varying thickness includes the steps of providing a shadow mask with an opening, providing a carrier plate, arranging a substrate on the carrier plate, and coating the substrate through the opening whilst rotating the carrier plate relative to the shadow mask. A plurality of zones of the substrates is swept and exposed from arcuate portions of the opening per each turn by a plurality of predetermined exposure times, respectively. The varying thickness of the thin film corresponds to variation of the predetermined exposure times.

A sputtering apparatus includes a chamber configured to provide a space where a deposition process is performed on a substrate, a substrate holder configured to support the substrate within the chamber, and at least one turret-type target assembly located over the substrate, including a plurality of targets mounted thereon and adapted to operatively rotate by a predetermined angle about its longitudinal axis such that any one of the targets is off-axis aligned with respect to a film-deposited surface of the substrate.

A pulsed direct current sputtering system and method are disclosed. The system has a plasma chamber with two targets, two magnetrons and one anode, a first power source, and a second power source. The first power source is coupled to the first magnetron and the anode, and provides a cyclic first-power-source voltage with a positive potential and a negative potential during each cycle between the anode and the first magnetron. The second power source is coupled to the second magnetron and the anode, and provides a cyclic second-power-source voltage. The controller phase-synchronizes and controls the first-power-source voltage and second-power-source voltage to apply a combined anode voltage, and phase-synchronizes a first magnetron voltage with a second magnetron voltage, wherein the combined anode voltage applied to the anode has a magnitude of at least 80 percent of a magnitude of a sum of the first magnetron voltage and the second magnetron voltage.