Abstract: A filament member configured to discharge thermions may be employed in an ion source of an ion implantation apparatus. A filament member may include an anode disposed around a central portion of the filament member, a cathode disposed around a periphery of the filament and/or enclosing the anode, and at least one conductive path disposed between the anode and the cathode to discharge the thermions.

Abstract: A plasma based ion implantation system capable of generating a capacitively coupled plasma having beneficial characteristics for an ion implantation, including the generation of necessary ions and radicals only for an ion implantation process instead of generating an inductively coupled plasma, which generates unnecessary ions and excessively dissociates radicals. The plasma based ion implantation system easily controls plasma ions implanted by cleaning a vacuum chamber, minimizes problems of unnecessary deposition and occurrence of contaminants and increases the number of components used only for the plasma ion implantion by reducing the deposition of polymer layer on a workpiece. The plasma based ion implantation system easily control uniformity of the plasma by using a flat type electrode, thereby easily ensuring uniformity of plasma ions implanted into the workpiece.

Abstract: A filament member configured to discharge thermions may be employed in an ion source of an ion implantation apparatus. A filament member may include an anode disposed around a central portion of the filament member, a cathode disposed around a periphery of the filament and/or enclosing the anode, and at least one conductive path disposed between the anode and the cathode to discharge the thermions.

Abstract: A filament member, ion source, and an ion implantation apparatus. The filament member may have a plate shape, and the thermoelectron emitter may include slots and a plurality of conductive paths disposed around the slots to emit thermoelectrons.

Abstract: In a method of doping ions into an object, such as a substrate, using plasma, a doping gas may be provided between first and second electrodes in a chamber. An electric field may be formed between the first and the second electrodes to excite the doping gas to a plasma state. The electric field may be formed by applying a first power having a first positive electric potential and a second power having a second positive electric potential, the second positive electric potential being higher than the first positive electric potential. The electric field may be reversed in direction by blocking the second power from being applied to the second electrode. Accumulated ions on the substrate may be effectively neutralized by introducing electrons toward the substrate so that arcing generation may be prevented.

Abstract: A method of doping ions into an object using plasma, including providing a doping gas between a first electrode and a second electrode, where an object is disposed between the first and the second electrodes, applying a first power to the first electrode and grounding the second electrode, exciting the doping gas to a plasma state, directing ions toward the object to be doped, applying a second power to the second electrode and grounding the first electrode, and counting a dose of the ions directed toward the second electrode, and an apparatus for performing the same.

Abstract: The present invention can provide ion implanter devices including an arc chamber including at least a first inner region and a second inner region, an electron emitting device disposed in the arc chamber adjacent the first inner region and adapted to emit electrons, an electron returning device disposed in the arc chamber adjacent the second inner region and adapted to return at least some of the electrons emitted from the electron emitting device into the second inner region; and an electric field and magnetic field generating device adapted to provide a magnetic field to the arc chamber, wherein at least one inner wall of the arc chamber has a convex surface.

Abstract: In an ion implanting apparatus and an ion implanting method using the same, the ion implanting apparatus includes a disk chamber containing a rotatable disk, a wafer mounted on the rotatable disk, and a charge sensor for monitoring a charged state of the wafer, the charge sensor being fixed to the disk chamber to be adjacent to and facing a surface of the wafer. An output of the charge sensor may be used as feedback to control the charged state of the wafer.

Abstract: The present invention can provide ion implanter devices including an arc chamber including at least a first inner region and a second inner region, an electron emitting device disposed in the arc chamber adjacent the first inner region and adapted to emit electrons, an electron returning device disposed in the arc chamber adjacent the second inner region and adapted to return at least some of the electrons emitted from the electron emitting device into the second inner region; and an electric field and magnetic field generating device adapted to provide a magnetic field to the arc chamber, wherein at least one inner wall of the arc chamber has a convex surface.

Abstract: In an ion implanting apparatus and an ion implanting method using the same, the ion implanting apparatus includes a disk chamber containing a rotatable disk, a wafer mounted on the rotatable disk, and a charge sensor for monitoring a charged state of the wafer, the charge sensor being fixed to the disk chamber to be adjacent to and facing a surface of the wafer. An output of the charge sensor may be used as feedback to control the charged state of the wafer.

Abstract: A polarity exchanger and ion implanter include a stripping canal for passing an ion beam therethrough, a gas supply unit for providing a stripping gas into the stripping canal to change a polarity of the ion beam, a gas circulation unit for circulating the stripping gas, a flow meter for measuring a flow rate of the stripping gas, an ammeter for measuring a driving current applied to the gas circulation unit for operating the gas circulation unit, and a monitoring unit for generating a control signal to control a process for changing the polarity of the ion beam in accordance with the measured flow rate of the stripping gas and the measured driving current. The polarity exchanger and ion implanter having the polarity exchanger may prevent generation of metallic contaminants caused by a flow rate variation of the stripping gas or deterioration of a component of the gas circulation unit.

Abstract: A method and an apparatus for measuring an inclination angle of an ion beam when ions are implanted into a semiconductor wafer include an ion current measuring section having a Faraday cup assembly which is rotatably installed, an angle varying section for adjusting an alignment angle of the Faraday cup assembly, and an inclination angle measuring section for measuring the inclination angle of the ion beam based on a variation of the ion current caused by a variation of the alignment angle of the Faraday cup assembly. By measuring the inclination angle of the ion beam, the incident angle of the ion beam, which is incident into the wafer during the ion implantation process, can be precisely adjusted to a predetermined critical angle. Accordingly, the channeling effect and shadow effect can be effectively prevented. The amount of the ions included in the ion beam can be precisely measured, so the amount of ions implanted into the wafer can be precisely adjusted.

Abstract: Chemical vapor deposition (CVD) processing equipment for use in fabricating a semiconductor device requiring deposition of an insulation layer or a metal layer includes a chamber having an exhaust line in a lower central portion thereof, a heater block for supporting a wafer to be supplied in an interior of the chamber, the heater block having a heating plate in an interior thereof, a support shaft for supporting the heater block, and an electrical wire for providing an electrical connection to the heating plate. The support shaft extends through a bottom of the chamber. The electrical wire extends through the bottom of the chamber within the support shaft.

Abstract: A polarity exchanger and ion implanter include a stripping canal for passing an ion beam therethrough, a gas supply unit for providing a stripping gas into the stripping canal to change a polarity of the ion beam, a gas circulation unit for circulating the stripping gas, a flow meter for measuring a flow rate of the stripping gas, an ammeter for measuring a driving current applied to the gas circulation unit for operating the gas circulation unit, and a monitoring unit for generating a control signal to control a process for changing the polarity of the ion beam in accordance with the measured flow rate of the stripping gas and the measured driving current. The polarity exchanger and ion implanter having the polarity exchanger may prevent generation of metallic contaminants caused by a flow rate variation of the stripping gas or deterioration of a component of the gas circulation unit.

Abstract: A heater assembly of a semiconductor device manufacturing apparatus minimizes a temperature difference between a peripheral portion and a central portion of the wafer being processed in the apparatus. The heater assembly includes a unitary resistive heating member in the form of a disc, heat blocks that divide the peripheral portion and central portion of the upper surface of the disc into respective heating sections, a support for supporting the heating member, and an electric power source for supplying electric current to the unitary heating member. The widths of the heating sections become greater towards the center of the heater, and thus the electrical resistance of the heater also increases in a direction towards the center of the heater. The power source for the heater includes a lead that extends from the bottom surface of the heater to a bottom portion of the heater support.

Abstract: An apparatus for use in orienting an object at a reference angle includes a pin gauge having at least two projections located at an end of the body of the apparatus. The projections are located at certain X Y coordinates of an X, Y Z Cartesian coordinate system. A horizontal support supports the body so as to be movable horizontally in the longitudinal direction of the projections. A mechanical drive member is operable to move the body mechanically in the horizontal direction. The apparatus may also include a vertical support and vertical drive member. The pin gauge is mechanically moved into contact with a surface of an object to provide a reference angle for the object. Then the object is pivoted, if necessary, to bring the surface into point contact with all of the projections of the pin gauge, whereupon the object is oriented at the reference angle.

Abstract: A method and an apparatus for measuring an inclination angle of an ion beam when ions are implanted into a semiconductor wafer include an ion current measuring section having a Faraday cup assembly which is rotatably installed, an angle varying section for adjusting an alignment angle of the Faraday cup assembly, and an inclination angle measuring section for measuring the inclination angle of the ion beam based on a variation of the ion current caused by a variation of the alignment angle of the Faraday cup assembly. By measuring the inclination angle of the ion beam, the incident angle of the ion beam, which is incident into the wafer during the ion implantation process, can be precisely adjusted to a predetermined critical angle. Accordingly, the channeling effect and shadow effect can be effectively prevented. The amount of the ions included in the ion beam can be precisely measured, so the amount of ions implanted into the wafer can be precisely adjusted.

Abstract: A parameter monitoring apparatus for a high voltage chamber in a semiconductor wafer processing system monitors parameters in the high voltage chamber in real time by converting an electrical signal generated from the high voltage chamber into an optical signal using an electro-optical converter. The optical signal is then converted back into an electrical signal again by an opto-electrical converter. The parameters can be monitored in real time without damaging measurement devices, since they are not influenced by the potential difference between the high voltage chamber and the measurement device.

Abstract: An electrostatic chuck of an ion implanter includes a base, a platen mounted on the base, and a clamp mechanically fixing the platen on the base. The clamp has a fixing member latched to the platen and coupling bolts that fix the fixing member to the base.

Abstract: A heater assembly of a semiconductor device manufacturing apparatus minimizes a temperature difference between a peripheral portion and a central portion of the wafer being processed in the apparatus. The heater assembly includes a unitary resistive heating member in the form of a disc, heat blocks that divide the peripheral portion and central portion of the upper surface of the disc into respective heating sections, a support for supporting the heating member, and an electric power source for supplying electric current to the unitary heating member. The widths of the heating sections become greater towards the center of the heater, and thus the electrical resistance of the heater also increases in a direction towards the center of the heater. As a result, more heat is generated at the peripheral portion of the heater than at the central portion of the heater. The power source for the heater includes a lead that extends from the bottom surface of the heater to a bottom portion of the heater support.