Abstract: Systems and methods for controlling a process applied to a substrate within a plasma chamber are described. The systems and methods include generating and supplying odd harmonic signals and summing the odd harmonic signals to generate an added signal. The added signal is supplied to an electrode within the plasma chamber for processing the substrate. The use of odd harmonic signals facilitates high aspect ratio etching of the substrate.

Abstract: Systems and methods for providing a multi regime plasma wafer processing are described. The systems and methods have three states. During a first one of the states, an etching operation is performed. In a second one of the states, a power level of a kilohertz radio frequency signal is greater than zero to increase directionality of ions that are incident on a bottom surface of a stack layer. In a third one of the states, there is a reduction in a loss of mask on top of the stack layer and deposition may be performed.

Abstract: Systems and methods for achieving a pre-determined factor associated with the edge region within the plasma chamber is described. One of the methods includes providing an RF signal to a main electrode within the plasma chamber. The RF signal is generated based on a frequency of operation of a first RF generator. The method further includes providing another RF signal to an edge electrode within the plasma chamber. The other RF signal is generated based on the frequency of operation of the first RF generator. The method includes receiving a first measurement of a variable, receiving a second measurement of the variable, and modifying a phase of the other RF signal based on the first measurement and the second measurement. The method includes changing a magnitude of a variable associated with a second RF generator to achieve the pre-determined factor.

Abstract: Systems and methods for providing a multi regime plasma wafer processing are described. The systems and methods have three states. During a first one of the states, an etching operation is performed. In a second one of the states, a power level of a kilohertz radio frequency signal is greater than zero to increase directionality of ions that are incident on a bottom surface of a stack layer. In a third one of the states, there is a reduction in a loss of mask on top of the stack layer and deposition may be performed.

Abstract: Systems and methods for controlling directionality of ion flux at an edge region within a plasma chamber are described. One of the systems includes a radio frequency (RF) generator that is configured to generate an RF signal, an impedance matching circuit coupled to the RF generator for receiving the RF signal to generate a modified RF signal, and a plasma chamber. The plasma chamber includes an edge ring and a coupling ring located below the edge ring and coupled to the first impedance matching circuit to receive the modified RF signal. The coupling ring includes an electrode that generates a capacitance between the electrode and the edge ring to control the directionality of the ion flux upon receiving the modified RF signal.

Abstract: A wafer support structure for use in a chamber used for semiconductor fabrication of wafers is provided. The wafer support structure includes a dielectric block. A first electrode is embedded in a top half of the dielectric block. The first electrode is configured for connection to a direct current (DC) power source. A second electrode is embedded in a bottom half of the dielectric block. A vertical connection is embedded in the dielectric block for electrically coupling the second electrode to the first electrode.

Abstract: A plasma chamber is provided to increase conductance within the plasma chamber and to increase uniformity of the conductance. A radio frequency (RF) path for supplying power to the plasma chamber is symmetric with respect to a center axis of the plasma chamber. Moreover, pumps used to remove materials from the plasma chamber are located symmetric with respect to the center axis. The symmetric arrangements of the RF paths and the pumps facilitate an increase in conductance uniformity within the plasma chamber.

Abstract: An impedance matching circuit (IMC) is described. The IMC includes a first circuit that includes a first plurality of tuning elements defined along a path. The first circuit has an input coupled to a kilohertz (kHz) radio frequency (RF) generator. The first circuit is coupled to an output. The IMC further includes a second circuit having a second plurality of tuning elements. The second circuit has an input coupled to a megahertz (MHz) RF generator and is coupled to the output. The IMC includes a uniformity control circuit (UCC) defined from at least one of the plurality of tuning elements of the first circuit. The UCC is connected serially along the path of the first circuit to define a capacitance that at least partially influences a radial uniformity profile in an etch rate produced by a plasma chamber.

Abstract: Systems and methods for controlling directionality of ion flux at an edge region within a plasma chamber are described. One of the systems includes a radio frequency (RF) generator that is configured to generate an RF signal, an impedance matching circuit coupled to the RF generator for receiving the RF signal to generate a modified RF signal, and a plasma chamber. The plasma chamber includes an edge ring and a coupling ring located below the edge ring and coupled to the first impedance matching circuit to receive the modified RF signal. The coupling ring includes an electrode that generates a capacitance between the electrode and the edge ring to control the directionality of the ion flux upon receiving the modified RF signal.

Abstract: Systems and methods for controlling a process applied to a substrate within a plasma chamber are described. The systems and methods include generating and supplying odd harmonic signals and summing the odd harmonic signals to generate an added signal. The added signal is supplied to an electrode within the plasma chamber for processing the substrate. The use of odd harmonic signals facilitates high aspect ratio etching of the substrate.

Abstract: An apparatus for processing a substrate is provided. A first coolant gas pressure system, a second coolant gas pressure system, a third coolant gas pressure system, and a fourth coolant gas pressure system are provided to provide independent gas pressures. An electrostatic chuck has a chuck surface with a center point and a radius and comprises a first plurality of coolant gas ports further than a first radius from a center point, a second plurality of coolant gas ports spaced between the first radius from the center point and a second radius from the center point, a third plurality of coolant gas ports spaced between the second radius from the center point and a third radius from the center point, and a fourth plurality of coolant gas ports is spaced within the third radius from the center point. An outer sealing band extends around the chuck surface.

Abstract: An Electrostatic Chuck (ESC) in a chamber of a semiconductor manufacturing apparatus is presented for eliminating cooling-gas light-up. One wafer support includes a baseplate connected to a radiofrequency power source, a dielectric block, gas supply channels for cooling the wafer bottom, and first and second electrodes. The dielectric block is situated above the baseplate and supports the wafer when present. The first electrode is embedded in the top half of the dielectric block, where the top surface of the first electrode is substantially parallel to a top surface of the dielectric block, and the first electrode is connected to a DC power source. Further, the second electrode is embedded in a bottom half of the dielectric block, the second electrode being electrically connected to the first electrode, where the bottom surface of the second electrode is substantially parallel to a top surface of the baseplate.

Abstract: A semiconductor substrate processing system includes a chamber that includes a processing region and a substrate support. The system includes a top plate assembly disposed within the chamber above the substrate support. The top plate assembly includes first and second sets of plasma microchambers each formed into the lower surface of the top plate assembly. A first network of gas supply channels are formed through the top plate assembly to flow a first process gas to the first set of plasma microchambers to be transformed into a first plasma. A set of exhaust channels are formed through the top plate assembly. The second set of plasma microchambers are formed inside the set of exhaust channels. A second network of gas supply channels are formed through the top plate assembly to flow a second process gas to the second set of plasma microchambers to be transformed into a second plasma.

Abstract: A plasma chamber is provided to increase conductance within the plasma chamber and to increase uniformity of the conductance. A radio frequency (RF) path for supplying power to the plasma chamber is symmetric with respect to a center axis of the plasma chamber. Moreover, pumps used to remove materials from the plasma chamber are located symmetric with respect to the center axis. The symmetric arrangements of the RF paths and the pumps facilitate an increase in conductance uniformity within the plasma chamber.

Abstract: Systems and methods for controlling a process applied to a substrate within a plasma chamber are described. The systems and methods include generating and supplying odd harmonic signals and summing the odd harmonic signals to generate an added signal. The added signal is supplied to an electrode within the plasma chamber for processing the substrate. The use of odd harmonic signals facilitates high aspect ratio etching of the substrate.

Abstract: Systems and methods for providing a multi regime plasma wafer processing are described. The systems and methods have three states. During a first one of the states, an etching operation is performed. In a second one of the states, a power level of a kilohertz radio frequency signal is greater than zero to increase directionality of ions that are incident on a bottom surface of a stack layer. In a third one of the states, there is a reduction in a loss of mask on top of the stack layer and deposition may be performed.

Abstract: An impedance matching circuit (IMC) is described. The impedance matching circuit includes a first circuit. The first circuit has an input coupled to a kilohertz (kHz) radio frequency (RF) generator. The IMC includes a second circuit. The second circuit has an input coupled to a low frequency megahertz (MHz) RF generator. The IMC includes a third circuit. The third circuit has an input coupled to a high frequency MHz RF generator. The IMC includes an output of the first, second, and third circuits coupled to an input of an RF transmission line. The first circuit and the second circuit provide isolation between a kHz RF signal sent through the first circuit and a low frequency MHz RF signal sent through the second circuit.

Abstract: A semiconductor substrate processing system includes a chamber that includes a processing region and a substrate support. The system includes a top plate assembly disposed within the chamber above the substrate support. The top plate assembly includes first and second sets of plasma microchambers each formed into the lower surface of the top plate assembly. A first network of gas supply channels are formed through the top plate assembly to flow a first process gas to the first set of plasma microchambers to be transformed into a first plasma. A set of exhaust channels are formed through the top plate assembly. The second set of plasma microchambers are formed inside the set of exhaust channels. A second network of gas supply channels are formed through the top plate assembly to flow a second process gas to the second set of plasma microchambers to be transformed into a second plasma.

Abstract: Systems and methods for controlling directionality of ion flux at an edge region within a plasma chamber are described. One of the systems includes a radio frequency (RF) generator that is configured to generate an RF signal, an impedance matching circuit coupled to the RF generator for receiving the RF signal to generate a modified RF signal, and a plasma chamber. The plasma chamber includes an edge ring and a coupling ring located below the edge ring and coupled to the first impedance matching circuit to receive the modified RF signal. The coupling ring includes an electrode that generates a capacitance between the electrode and the edge ring to control the directionality of the ion flux upon receiving the modified RF signal.

Abstract: Systems and methods for achieving a pre-determined factor associated with the edge region within the plasma chamber is described. One of the methods includes providing an RF signal to a main electrode within the plasma chamber. The RF signal is generated based on a frequency of operation of a first RF generator. The method further includes providing another RF signal to an edge electrode within the plasma chamber. The other RF signal is generated based on the frequency of operation of the first RF generator. The method includes receiving a first measurement of a variable, receiving a second measurement of the variable, and modifying a phase of the other RF signal based on the first measurement and the second measurement. The method includes changing a magnitude of a variable associated with a second RF generator to achieve the pre-determined factor.