Disclosed herein is a connector for electrically connecting a feedthrough of a vacuum tool to a high voltage power source, the connector comprising: a connector wire assembly configured to be in electrical connection with a high voltage power source; and a connector insulator comprising a channel configured to extend into the connector insulator and to receive a feedthrough pin so as to electrically connect the connector wire assembly with the feedthrough pin; wherein the connector insulator is configured to engage with the feedthrough so that a boundary surface of the connector insulator extends substantially bi-directionally in the direction of the longitudinal axis of the channel.

Disclosed herein is a connector for electrically connecting a feedthrough of a vacuum tool to a high voltage power source, the connector comprising: a connector wire assembly configured to be in electrical connection with a high voltage power source; and a connector insulator comprising a channel configured to extend into the connector insulator and to receive a feedthrough pin so as to electrically connect the connector wire assembly with the feedthrough pin; wherein the connector insulator is configured to engage with the feedthrough so that a boundary surface of the connector insulator extends substantially bi-directionally in the direction of the longitudinal axis of the channel.

Disclosed herein is a system for pulsed DC biasing and clamping a substrate. The system can include a plasma chamber having an ESC for supporting a substrate. An electrode is embedded in the ESC and is electrically coupled to a biasing and clamping circuit. The biasing and clamping circuit includes at least a shaped DC pulse voltage source and a clamping network. The clamping network includes a DC voltage source and a diode, and a resistor. The shaped DC pulse voltage source and the clamping network are connected in parallel. The biasing and clamping network automatically maintains a substantially constant clamping voltage, which is a voltage drop across the electrode and the substrate when the substrate is biased with pulsed DC voltage, leading to improved clamping of the substrate.

Disclosed herein is a system for pulsed DC biasing and clamping a substrate. The system can include a plasma chamber having an ESC for supporting a substrate. An electrode is embedded in the ESC and is electrically coupled to a biasing and clamping circuit. The biasing and clamping circuit includes at least a shaped DC pulse voltage source and a clamping network. The clamping network includes a DC voltage source and a diode, and a resistor. The shaped DC pulse voltage source and the clamping network are connected in parallel. The biasing and clamping network automatically maintains a substantially constant clamping voltage, which is a voltage drop across the electrode and the substrate when the substrate is biased with pulsed DC voltage, leading to improved clamping of the substrate.

Embodiments of a lift apparatus for use in a substrate processing chamber are provided herein. In some embodiments, a lift apparatus includes: a plurality of first lift pin assemblies configured to raise or lower a substrate having a given diameter when disposed thereon, wherein each of the first lift pin assemblies includes a first lift pin disposed on a first bellows assembly; a plurality of second lift pin assemblies arranged in a circle having a diameter greater than the given diameter and configured to raise or lower an annular chamber component, wherein each of the second lift pin assemblies includes a second lift pin disposed on a second bellows assembly; an actuator; and a lift assembly coupled to the actuator and configured to raise or lower each of the first lift pin assemblies and the second lift pin assemblies by movement of the actuator.

Embodiments of a lift apparatus for use in a substrate processing chamber are provided herein. In some embodiments, a lift apparatus includes: a plurality of first lift pin assemblies configured to raise or lower a substrate having a given diameter when disposed thereon, wherein each of the first lift pin assemblies includes a first lift pin disposed on a first bellows assembly; a plurality of second lift pin assemblies arranged in a circle having a diameter greater than the given diameter and configured to raise or lower an annular chamber component, wherein each of the second lift pin assemblies includes a second lift pin disposed on a second bellows assembly; an actuator; and a lift assembly coupled to the actuator and configured to raise or lower each of the first lift pin assemblies and the second lift pin assemblies by movement of the actuator.

The invention provides a power supply module and a charged particle beam device that are capable of reducing ripple noise. A high-voltage generation circuit 101 includes booster circuits CPa and CPb of two systems that are configured to be symmetrical to each other, and performs a boosting operation by using a capacitive element and a diode in the booster circuits CPa and CPb of the two systems. The high-voltage generation circuit is housed in a housing and a reference power supply voltage is applied thereto. A left electrode 102a is fixedly provided in the vicinity of one of the booster circuits CPa and CPb of the two systems in the housing, and a right electrode 102b is fixedly provided in the vicinity of the other of the booster circuits CPa and CPb of the two systems in the housing. A stray capacitance adjustment circuit 100a adjusts capacitance values of stray capacitances of the booster circuits CPa and CPb of the two systems by electrically controlling an electrical connection characteristic between the left electrode 102a and the reference power supply voltage 104 and an electrical connection characteristic between the right electrode 102b and the reference power supply voltage 104

The invention provides a power supply module and a charged particle beam device that are capable of reducing ripple noise. A high-voltage generation circuit 101 includes booster circuits CPa and CPb of two systems that are configured to be symmetrical to each other, and performs a boosting operation by using a capacitive element and a diode in the booster circuits CPa and CPb of the two systems. The high-voltage generation circuit is housed in a housing and a reference power supply voltage is applied thereto. A left electrode 102a is fixedly provided in the vicinity of one of the booster circuits CPa and CPb of the two systems in the housing, and a right electrode 102b is fixedly provided in the vicinity of the other of the booster circuits CPa and CPb of the two systems in the housing. A stray capacitance adjustment circuit 100a adjusts capacitance values of stray capacitances of the booster circuits CPa and CPb of the two systems by electrically controlling an electrical connection characteristic between the left electrode 102a and the reference power supply voltage 104 and an electrical connection characteristic between the right electrode 102b and the reference power supply voltage 104

An amplifier circuit includes a constant current circuit for outputting a constant current signal at its output terminal, an operational amplifier for outputting an amplified control signal based on the first voltage signal, and an amplified voltage output circuit for outputting a second voltage signal based on both the constant current signal and the amplified control signal. The constant current circuit has a light-emitting device having one end supplied with the constant voltage signal and another end supplied with ground potential, a light responsive electricity generating device for outputting a drive signal in response to light emitted by the light-emitting device, a first transistor generating the constant current signal based on the amplified voltage signal applied thereto and to output the constant current signal; and a current control circuit for detecting the value of the constant current signal and controlling the supply of the drive signal based on the detection.

An amplifier circuit includes a constant current circuit for outputting a constant current signal at its output terminal, an operational amplifier for outputting an amplified control signal based on the first voltage signal, and an amplified voltage output circuit for outputting a second voltage signal based on both the constant current signal and the amplified control signal. The constant current circuit has a light-emitting device having one end supplied with the constant voltage signal and another end supplied with ground potential, a light responsive electricity generating device for outputting a drive signal in response to light emitted by the light-emitting device, a first transistor generating the constant current signal based on the amplified voltage signal applied thereto and to output the constant current signal; and a current control circuit for detecting the value of the constant current signal and controlling the supply of the drive signal based on the detection.