Abstract: A width of a groove of a cathode holder and a thickness of a cathode conductor are determined so that a dimension which is obtained by subtracting the thickness from the width is equal to a gap length which has a predetermined length, and which is between a filament and a cathode. Then, the cathode holder is rearward pushed to cause a front end face of the groove 26 to butt against the cathode conductor, and the cathode conductor and filament conductors are coupled and fixed to each other via an electrically insulating material. And then, the filament is forward moved to butt against the cathode, and the filament is fixed to the filament conductors. After that, the cathode holder is forward pulled to cause a projection to butt against the cathode conductor, and the cathode holder is fixed to the cathode conductor.

Abstract: To increase a transport efficiency of an ion beam by correcting Y-direction diffusion caused by the space charge effect of the ion beam between an ion beam deflector, which separates the ion beam and neutrons from each other, and a target. An ion implantation apparatus has a beam paralleling device that bends an ion beam scanned in an X direction by magnetic field to be parallel and draws a ribbon-shaped ion beam. The beam paralleling device serves also as an ion beam deflector that deflects the ion beam by magnetic field to separates neutrons from the ion beam. In the vicinity of an outlet of the beam paralleling device, there is provided an electric field lens having a plurality of electrodes opposed to each other in a Y direction with a space for passing the ion beam and narrowing the ion beam in the Y direction.

Abstract: A magnet used in an ion beam irradiation apparatus includes a pair of magnetic poles arranged facing each other on an inner side of the magnet across an ion beam; a plurality of magnetic field concentrating members that are arranged on each of the opposing surfaces of the magnetic poles and that perform a function of trapping electrons between the magnetic poles; and a protective member that covers opposing surfaces of the magnetic field concentrating members.

Abstract: A repeller structure is provided in a plasma generating chamber of an ion source facing a cathode that emits electrons for ionizing a source gas in the plasma generating chamber to generate a plasma. The repeller structure reflects the ions toward the cathode. The repeller structure includes a sputtering target that is sputtered by the plasma to emit predetermined ions, the sputtering target including a through hole that connects a sputtering surface and a back surface of the sputtering target; and an electrode body that is inserted in the through hole, the electrode body including a repeller surface that is exposed to the sputtering surface side through the through hole.

Abstract: Using a beam current of an ion beam, a dose amount to a substrate, and a reference scan speed, a scan number of the substrate is calculated as an integer value in which digits after a decimal point are truncated. If the scan number is smaller than 2, the process is aborted. If the scan number is equal to or larger than 2, it is determined whether the scan number is even or odd. If the scan number is even, the current scan number is set as a practical scan number. If the scan number is odd, an even scan number which is smaller by 1 than the odd scan number is obtained, and the obtained even scan number is set as a practical scan number. A practical scan speed of the substrate is calculated by using the practical scan number, the beam current, and the dose amount.

Abstract: Using a beam current of an ion beam, and a dose amount to a substrate, and an initial value of a scan number of the substrate set to 1, a scan speed of the substrate is calculated. If the scan speed is within the range, the current scan number and the current scan speed are set as a practical scan number and a practical scan speed, respectively. If the scan speed is higher than the upper limit of the range, the calculation process is aborted. If the scan speed is lower than the lower limit of the range, the scan number is incremented by one to calculate a corrected scan number. A corrected scan speed is calculated by using the corrected scan number, etc. The above steps are repeated until the corrected scan speed is within the allowable scan speed range.

Abstract: An ion beam irradiating apparatus has a field emission electron source 10 which is disposed in a vicinity of a path of the ion beam 2, and which emits electrons 12. The field emission electron source 10 is placed in a direction along which an incident angle formed by the electrons 12 emitted from the electron source 10 and a direction parallel to the traveling direction of the ion beam 2 is in the range from ?15 deg. to +45 deg. (an inward direction of the ion beam 2 is +, and an outward direction is ?).

Abstract: Beam detectors configuring a beam monitor are connected to a single current measurement apparatus through respective switches. If a width of a beam incident hole of each of the beam detectors 32 in the X direction is Wf, a gap between the beam incident holes of adjacent beam detectors in the X direction is Ws, a beam width of the ion beam in the X direction is Wb, a total number of beam detectors is “p”, and “n” is an integer of 0?n?(p?2) and satisfying Wb<{n·Wf+(n+1)Ws}, a measuring process of receiving the ion beam by the beam monitor and measuring the waveforms of the beam currents flowing into the current measurement apparatus in a state in which the plurality of switches skipped by “n” are simultaneously switched ON and a switching process of switching the switches simultaneously switched ON under the condition, are repeated.

Abstract: An ion implantation apparatus is provided with first and second magnets arranged so as to face each other in a Y direction across a path for a ribbon-shaped ion beam. The first and second magnets cross a traveling direction of the ribbon-shaped ion beam. Each of the first and second magnets has a pair of magnetic poles on an inlet side and on an outlet side of the ion beam. The polarities thereof are opposite between the first magnet and the second magnet.

Abstract: An ion implanter includes an implantation chamber into which an ion beam is introduced, a holder for holding substrates on two columns of a first column and a second column in an X-direction, and a holder driving unit having a function of setting the holder in a horizontal state and then positioning the holder in a substrate exchange position and a function of setting the holder in a standing state and then driving reciprocally and linearly the holder along the X-direction in an irradiation area of the ion beam. Also, the ion implanter includes two load lock mechanisms, and two substrate carrying units equipped with arms, which carry the substrates between the load lock mechanisms and a substrate exchange position respectively, every two arms.

Abstract: This ion source generates a ribbon-like ion beam whose dimension in the Y direction is larger than the dimension in the X direction. This ion source includes a plasma generating vessel having an ion extraction port extending in the Y direction, a plurality of cathodes arranged in a plurality of stages along the Y direction on one side in the X direction in the plasma generating vessel, a reflecting electrode arranged on the other side in the X direction in the plasma generating vessel opposite to the cathodes, and electromagnets for generating magnetic fields along the X direction in regions including the plurality of cathodes in the plasma generating vessel.

Abstract: An extraction electrode of an ion source is dividedly configured by a first extraction electrode and a second extraction electrode. DC power supplies which form a potential difference between the electrodes, a camera which takes an image of the ion beam to output image data of the ion beam, and a rear-stage beam instrument which measures the beam current of the ion beam that has passed through the analysis slit are disposed.

Abstract: An ion implanting apparatus is provided. The ion implanting apparatus includes a beam scanner, a beam collimator and a unipotential lens which is disposed between said beam scanner and said beam collimator, and which includes first, second, third, and fourth electrodes arranged in an ion beam traveling direction while forming first, second, and third gaps, said first and fourth electrodes being electrically grounded, wherein positions of centers of curvature of said first and third gaps of said unipotential lens coincide with a position of a scan center of said beam scanner, and wherein a position of a center of curvature of said second gap of said unipotential lens is shifted from the position of the scan center of said beam scanner toward a downstream or upstream side in the ion beam traveling direction.

Abstract: An ion source is to extract a ribbon-shaped ion beam longer in the Y direction in the Z direction and provided with a plasma generating chamber, a plasma electrode which is disposed near the end of the plasma generating chamber in the Z direction and has an ion extracting port extending in the Y direction, a plurality of cathodes for emitting electrons into the plasma generating chamber to generate a plasma and arranged in a plurality of stages along the Y direction, and a magnetic coil which generates magnetic fields along the Z direction in a domain containing the plurality of cathodes inside the plasma generating chamber.

Abstract: A cathode holder of a tubular shape is inserted into an opening for a cathode of a plasma generating chamber, the cathode holder positioned such that a surface thereof opposes or surrounds a side surface of a cathode. The cathode is held in the cathode holder so that a front surface of the cathode will be positioned on the same plane as, outward from, or inward from the inner wall surface. In the cathode holder is provided a tubular first heat shield surrounding the cathode with a space provided between the first heat shield and the cathode, a surface of the first heat shield positioned to oppose or surround the side surface of the cathode. At a rear end of the cathode is provided a filament. The gap between the cathode holder and the plasma generating chamber is filled with an electrical insulating material.

Abstract: A collimator magnet (CM) usable in an ion implantation system provides an exit ion beam with a large aperture, substantially parallel in one plane or orthogonal planes. The CM includes identical poles, defined by an incident edge receiving an ion beam, and an exit edge outputting the ion beam for implantation. Ion beam deflection takes place due to magnetic forces inside the CM and magnetic field fringe effects outside the CM. The CM incident and/or exit edge is shaped by solving a differential equation to compensate for magnetic field fringe effects and optionally, space charge effects and ion beam initial non-parallelism. The CM shape is obtained by imposing that the incidence or exit angle is substantially constant, or, incidence and exit angles have opposite sign but equal absolute values for each ray in the beam; or the sum of incidence and exit angles is a constant or a non-constant function.

Abstract: The plasma generating apparatus includes: an antenna chamber which is disposed adjacently to a plasma chamber that produces a plasma, and which is exhausted to vacuum; an antenna which is disposed in the antenna chamber, and which radiates a high-frequency wave; a partition plate which is made of an insulator, which separates the plasma chamber from the antenna chamber to block a gas from entering the antenna chamber, and which allows the high-frequency wave radiated from the antenna to pass through the partition plate; and a magnet device which is disposed outside the plasma chamber, and which generates a magnetic field for causing electron cyclotron resonance in the plasma chamber.

Abstract: An ion source is provided that can generate an ion beam in which the width is wide, the beam current is large, and the uniformity of the beam current distribution in the width direction is high, and that can prolong the lifetime of a cathode. The ion source 2a has: a plasma generating chamber 6 having an ion extraction port 8 extending in the X direction; a magnet 14 which generates a magnetic field 16 extending along the X direction, in the plasma generating chamber 6; indirectly-heated cathodes 20 which are placed respectively on the both sides of the plasma generating chamber 6 in the X direction, and which are used for generating a plasma i0 in the chamber 6, and increasing or decreasing the density of the whole of the plasma 10; and plural filament cathodes 32 which are juxtaposed in the X direction in the plasma generating chamber 6, and which are used for generating the plasma i0 in the chamber 6, and controlling the density distribution of the plasma 10.

Abstract: An illuminating device includes: a light source which is disposed outside a vacuum chamber; a light guide which guides the light emitted from the light source, into the vacuum chamber; a light projecting portion which is fixed in the vacuum chamber, and which emits the light guided by the light guide; a light receiving portion which is attached to a support table of a holder driving device, and which receives the light emitted from the light projecting portion in a state where a holder is positioned in a notch detecting position; a light guide which guides the light received by the light receiving portion; and a light emitting device which is attached to the support table, and which irradiates an outer circumferential portion of a substrate with the light guided by the light guide.

Abstract: An ion source includes a plasma generating chamber into which an ionization gas containing fluorine is introduced, a hot cathode provided on one side in the plasma generating chamber, an opposing reflecting electrode which is provided on other side in the plasma generating chamber and reflects electrons when a negative voltage is applied from a bias power supply to the opposing reflecting electrode, and a magnet for generating a magnetic field along a line, which connects the hot cathode and the opposing reflecting electrode, in the plasma generating chamber. The opposing reflecting electrode is formed of an aluminum containing material.