Wafer scale oblique angle etching of a semiconductor substrate is performed in a conventional plasma etch chamber by using a fixture that supports a multiple number of separate Faraday cages. Each cage is formed to include an angled grid surface and is positioned such that it will be positioned over a separate one of the die locations on the wafer surface when the fixture is placed over the wafer. The presence of the Faraday cages influences the local electric field surrounding each wafer die, re-shaping the local field to be disposed in alignment with the angled grid surface. The re-shaped plasma causes the reactive ions to follow a linear trajectory through the plasma sheath and angled grid surface, ultimately impinging the wafer surface at an angle. The selected geometry of the Faraday cage angled grid surface thus determines the angle at with the reactive ions will impinge the wafer.

A heating plate for use in a substrate support is configured to provide temperature profile control of a substrate supported on the substrate support in a vacuum chamber of a substrate processing apparatus. The heating plate includes an independently controllable heater zones operable to tune a temperature profile on an upper surface of the heating plate. The heater zones are each powered by two or more power lines wherein each power line is electrically connected to a different group of the heater zones and each respective heater zone is electrically connected to a different pair of power lines.

A method for manufacturing an array substrate, a film-etching monitoring and a film-etching monitoring device. The monitoring method comprises: monitoring and recording the transmittance reference value of a film after a film pattern is formed; and monitoring the transmittance present value of the film in real time in the process of etching an overcoating layer to form a through hole after the overcoating layer is formed on the film pattern, and monitoring the etching degree of the film by determining the variation between the transmittance present value and the transmittance reference value. The device comprises a plurality of light sources (3) and a plurality of light-sensitive probes (4) disposed in the chamber. The light sources (3) are configured to irradiate the film on a substrate; and the light-sensitive probes (4) are configured to sense the transmittance of the film.

A substrate processing apparatus includes a process chamber, and a turntable provided in the process chamber and including a substrate holding region formed in a top surface along a circumferential direction of the turntable. A surface area increasing region is provided in the top surface of the turntable around the substrate holding region and is configured to increase a surface area of the top surface of the turntable to an area larger than a surface area of a flat surface by including a concavo-convex pattern in its top surface. A process gas supply unit is configured to supply a process gas to the top surface of the turntable.

A system for controlling an etch process includes and etching tool, a metrology tool, and a controller. The etching tool is controllable via a set of control parameters and may execute a plurality of etch recipes containing values of the set of control parameters. The controller may direct the etching tool to execute a plurality of etch recipes on a plurality of metrology targets; direct the metrology tool to generate metrology data indicative of two or more etch characteristics on the plurality of metrology targets; determine one or more relationships between the two or more etch characteristics and the set of control parameters based on the metrology data; and generate, based on the one or more relationships, a particular etch recipe to constrain one of the two or more etch characteristics and maintain the remainder of the two or more etch characteristics within defined bounds.

The inventive concept provides a substrate treating apparatus. The substrate treating apparatus includes a process chamber having a treating space therein; a substrate support unit configured to support a substrate in the treating space; a gas supply unit configured to supply a process gas to the treating space; and a plasma source for generating a plasma from the process gas, and wherein the substrate support unit includes: a support plate on which the substrate is placed; a base which is positioned below the support plate; a first ring provided to surround the substrate placed on the support unit; a second ring provided below the first ring and having a through hole; and a ring lift pin assembly for lifting and lowering the first ring and the second ring, and wherein the ring lift pin assembly includes: a first pin provided to be inserted into the through hole and to lift and lower the first ring; a second pin in a hollow shaft shape to lift and lower the second ring and having a hole at which first pin passes through within; and a driving unit for driving the first pin and the second pin, and wherein the through hole overlaps the first ring when seen from above.

A method for achieving uniformity in an etch rate is described. The method includes receiving a voltage signal from an output of a match, and determining a positive crossing and a negative crossing of the voltage signal for each cycle of the voltage signal. The negative crossing of each cycle is consecutive to the positive crossing of the cycle. The method further includes dividing a time interval of each cycle of the voltage signal into a plurality of bins. For one or more of the plurality of bins associated with the positive crossing and one or more of the plurality of bins associated with the negative crossing, the method includes adjusting a frequency of a radio frequency generator to achieve the uniformity in the etch rate.

A plasma source array is provided. The plasma source array includes a plurality of hybrid plasma sourcelets disposed on a base plate. Each hybrid sourcelet includes a dielectric tube having an inner area and an outer surface; an inductively coupled plasma source for generating a inductively coupled plasma disposed proximate to the outer surface of the dielectric tube; a capacitively coupled plasma source for generating a capacitively coupled plasma disposed within the inner area of the dielectric tube; and a gas injection system configured to supply one or more process gases to the inner area of the dielectric tube. Plasma processing apparatuses incorporating the plasma source array and methods of use are also provided.

A method for applying RF power in a plasma process chamber is provided, including: generating a first RF signal; generating a second RF signal; generating a third RF signal; wherein the first, second, and third RF signals are generated at different frequencies; combining the first, second and third RF signals to generate a combined RF signal, wherein a wave shape of the combined RF signal is configured to approximate a sloped square wave shape; applying the combined RF signal to a chuck in the plasma process chamber.

The inventive concept relates to a substrate support unit provided in an apparatus for treating a substrate using plasma. In an embodiment, the substrate support unit includes a dielectric plate on which the substrate is placed, a lower electrode that is disposed under the dielectric plate and that has a first diameter, a power supply rod that applies RF power to the lower electrode and has a second diameter, and a ground member disposed under the lower electrode and spaced apart from the lower electrode by a first gap by an insulating member, the ground member including a plate portion having a through-hole formed therein through which the power supply rod passes, in which the through-hole has a third diameter.