Embodiments of the present disclosure provide a semiconductor processing apparatus and a magnetron mechanism thereof. The magnetron mechanism is applied to the semiconductor processing apparatus and includes a backplane, an outer magnetic pole, and an inner magnetic pole. The outer magnetic pole is arranged on a bottom surface of the backplane and encloses to form accommodation space. The inner magnetic pole is arranged on the bottom surface of the backplane and located in the accommodation space. The inner magnetic pole can move to change corrosion areas of the target material. The distance between the inner magnetic pole and the outer magnetic pole is always greater than a predetermined distance during the movement. With the semiconductor processing apparatus and the magnetron mechanism thereof of embodiments of the present disclosure can achieve the full target corrosion in a sputtering environment in a high-pressure state.

Implementations of the present disclosure relate to a sputtering target for a sputtering chamber used to process a substrate. In one implementation, a sputtering target for a sputtering chamber is provided. The sputtering target comprises a sputtering plate with a backside surface having radially inner, middle and outer regions and an annular-shaped backing plate mounted to the sputtering plate. The backside surface has a plurality of circular grooves which are spaced apart from one another and at least one arcuate channel cutting through the circular grooves and extending from the radially inner region to the radially outer region of sputtering plate. The annular-shaped backing plate defines an open annulus exposing the backside surface of the sputtering plate.

A target assembly is provided which is capable of preventing abnormal discharging from being generated between a projected portion of a backing plate and a side surface of a target, and which is also capable of surely preventing a bonding material that bonds the target and the backing plate together from seeping to the outside. The backing plate has a projected portion which is projected outward beyond an outer peripheral end of the target, and an annular shield plate is disposed to lie opposite to the projected portion so as to enclose the target in a state in which the target assembly is assembled onto a sputtering apparatus (SM). That portion of the backing plate to which the target gets bonded is defined as a bonding portion, and this bonding portion is protruded relative to the projected portion.

Evaporation source, in particular for use in a sputtering process or in a vacuum arc evaporation process, preferably a cathode vacuum arc evaporation process. The evaporation source includes an inner base body which is arranged in an outer carrier body and which is arranged with respect to the outer carrier body such that a cooling space in flow communication with an inlet and an outlet is formed between the base body and the carrier body. In accordance with the invention, the cooling space includes an inflow space and an outflow space, and the inflow space is in flow communication with the outflow space via an overflow connection for the cooling of the evaporation source such that a cooling fluid can be conveyed from the inlet via the inflow space the overflow connection and the outflow space to the outlet.

Various embodiments provide Molten Target Sputtering (MTS) methods and devices. The various embodiments may provide increases in the kinetic energy, increases in the energy latency, and/or increases in the flux density of molecules for better crystal formation at low temperature operation. The various embodiment MTS methods and devices may enable the growth of a single crystal Si.sub.1-xGe.sub.x film on a substrate heated to less than about 500° C. The various embodiment MTS methods and devices may provide increases in the kinetic energy, increases in the energy latency, and/or increases in the flux density of molecules without requiring the addition of extra systems.

An endblock for a rotatable sputtering target, such as a rotatable magnetron sputtering target, is provided. A sputtering apparatus, including one or more such endblock(s), includes locating the electrical contact(s) (e.g., brush(es)) between the collector and rotor in the endblock(s) in an area under vacuum (as opposed to in an area at atmospheric pressure).

A power transfer system is described for transfer of electrical power to a sputter target in a sputter device. It comprises a first part comprising a contact surface positionable against a first part of an endblock of the sputter device, a second part inseparably connected to the first part and a third part, and a third part comprising a contact surface positionable against a second part of the endblock or directly against a sputter target when mounted on the endblock. At least two of the three parts are formed as one monolithic piece. One of the parts of the power transfer system is resilient such that, when mounted, the power transfer system is clamped between the first part of the endblock and the second part of the endblock or the sputter target. This part is also responsible for the transfer of electrical power.

A sputtering apparatus is provided. The sputtering apparatus comprises a vacuum chamber in which a substrate is located; a target having one surface facing an inner surface of the vacuum chamber; a gas supplier configured to supply a gas for generating plasma in the vacuum chamber; a power supplier configured to supply a power to the target to generate the plasma, sputter the target, and form a film on the substrate; and an abnormality detector configured to detect abnormality caused by a temperature of the target.

Embodiments of a magnetron assembly and a processing system incorporating same are provided herein. In some embodiments, a magnetron assembly includes a body extending along a central axis of the magnetron assembly; a coolant feed structure extending through the body along the central axis to provide a coolant along the central axis to an area beneath the coolant feed structure; and a rotatable magnet assembly coupled to a bottom of the body and having a plurality of magnets.

A heating device having a heating element patterned into a robust MEMs substrate, wherein the heating element is electrically isolated from a fluid reservoir or bulk conductive sample, but close enough in proximity to an imagable window/area having the fluid or sample thereon, such that the sample is heated through conduction. The heating device can be used in a microscope sample holder, e.g., for SEM, TEM, STEM, X-ray synchrotron, scanning probe microscopy, and optical microscopy.