Abstract: A keyswitch, disposed on a base plate, includes a keycap and a scissors-like supporting structure. The scissors-like supporting structure is disposed on the base plate and supports the keycap. The scissors-like supporting structure includes a first supporting member and a second supporting member. The first supporting member includes a first engaging shaft and a second engaging shaft respectively engaged with the base plate and the keycap. The second supporting member is pivotally connected to the first supporting member and includes a third engaging shaft and a fourth engaging shaft respectively engaged with the base plate and the keycap. A line connected between the centers of gravity of the first and second engaging shaft is not perpendicular to the first and second engaging shaft. A line connected between the centers of gravity of the third and fourth engaging shaft is not perpendicular to the third and fourth engaging shaft.

Abstract: A membrane circuit board and a keyboard device having the same are provided in the invention. The membrane circuit board is defined with a plurality of key regions. Each of the key regions is with a pressing region and at least one light-pervious region thereon. The membrane circuit board comprising at least two light-pervious membranes stacked with each other, and at least one light-pervious adhesive layer sandwiched between the two light-pervious membranes and at least fully filled in the light-pervious region.

Abstract: A keyswitch, disposed on a base plate, includes a keycap and a scissors-like supporting structure. The scissors-like supporting structure is disposed on the base plate and supports the keycap. The scissors-like supporting structure includes a first supporting member and a second supporting member. The first supporting member includes a first engaging shaft and a second engaging shaft respectively engaged with the base plate and the keycap. The second supporting member is pivotally connected to the first supporting member and includes a third engaging shaft and a fourth engaging shaft respectively engaged with the base plate and the keycap. A line connected between the centers of gravity of the first and second engaging shaft is not perpendicular to the first and second engaging shaft. A line connected between the centers of gravity of the third and fourth engaging shaft is not perpendicular to the third and fourth engaging shaft.

Abstract: An ion implantation method and an ion implanter with a beam profiler are proposed in this invention. The method comprises setting scan conditions, detecting the ion beam profile, calculating the dose profile according to the detected ion beam profile and scan conditions, determining the displacement for ion implantation and implanting ions on a wafer surface. The ion implanter used the beam profiler to detect the ion beam profile, calculate dose profile and determine the displacement and used the displacement in ion implantation for optimizing, wherein the beam profiler comprises a body with ion channel and detection unit behind the ion channel in the body for beam profile detection. The beam profiler may be a 1-dimensional, 2-dimensional or angle beam profiler.

Abstract: A method capable of monitoring ion implantation. First, an ion beam and a workpiece are provided. Next, implant the workpiece by the ion beam and generate a profile having numerous signals relevant to respectively numerous relative positions between the ion beam and the workpiece, wherein the profile has at least a higher portion, a gradual portion and a lower portion. Therefore, by directly analyzing the profile without referring to a pre-determined profile and without using a profiler measuring the ion beam, some ion beam information may be acquired, such as beam height, beam width, ion beam current distribution on the ion beam cross-section, and so on, and the ion implantation may be monitored real-timely. Furthermore, when numerous workpieces are implanted in sequence, the profile(s) of one or more initially implanted workpiece(s) may be to generate a reference for calibrating the ion implantation of the following workpieces.

Abstract: A membrane circuit board and a keyboard device having the same are provided in the invention. The membrane circuit board is defined with a plurality of key regions. Each of the key regions is with a pressing region and at least one light-pervious region thereon. The membrane circuit board comprising at least two light-pervious membranes stacked with each other, and at least one light-pervious adhesive layer sandwiched between the two light-pervious membranes and at least fully filled in the light-pervious region.

Abstract: To select a relative velocity profile to be used in scanning an actual work piece with an ion implant beam of an ion implantation tool, the implantation of a virtual work piece is simulated. A dose distribution is calculated across the virtual work piece based on an implant beam profile and a relative velocity profile. A new relative velocity profile is then determined based on the calculated dose distribution and the relative velocity profile used in calculating the dose distribution. A new dose distribution is then calculated using the new relative velocity profile. A new relative velocity profile is determined and a corresponding new dose distribution is calculated iteratively until the new dose distribution meets one or more predetermined criteria. The new relative velocity profile is stored as the selected relative velocity profile when the new dose distribution meets the one or more predetermined criteria.

Abstract: An ion implantation method and an ion implanter with a beam profiler are proposed in this invention. The method comprises setting scan conditions, detecting the ion beam profile, calculating the dose profile according to the detected ion beam profile and scan conditions, determining the displacement for ion implantation and implanting ions on a wafer surface. The ion implanter used the beam profiler to detect the ion beam profile, calculate dose profile and determine the displacement and used the displacement in ion implantation for optimizing, wherein the beam profiler comprises a body with ion channel and detection unit behind the ion channel in the body for beam profile detection. The beam profiler may be a 1-dimensional, 2-dimensional or angle beam profiler.

Abstract: Initially, an ion beam is formed as an elongated shape incident on a wafer, where the shape has a length along a first axis longer than a diameter of the wafer, and a width along a second axis shorter than the diameter of the wafer. Then, a center of the wafer is moved along a scan path intersecting the ion beam at a movement velocity, and the wafer is rotated around at a rotation velocity simultaneously. During the simultaneous movement and rotation, the wafer is totally overlapped with the ion beam along the first axis when the wafer intersects with the ion beam, and the rotation velocity is at most a few times of the movement velocity. Both the movement velocity and the rotation velocity can be a constant or have a velocity profile relative to a position of the ion beam across the wafer.

Abstract: A method capable of monitoring ion implantation. First, an ion beam and a workpiece are provided. Next, implant the workpiece by the ion beam and generate a profile having numerous signals relevant to respectively numerous relative positions between the ion beam and the workpiece, wherein the profile has at least a higher portion, a gradual portion and a lower portion. Therefore, by directly analyzing the profile without referring to a pre-determined profile and without using a profiler measuring the ion beam, some ion beam information may be acquired, such as beam height, beam width, ion beam current distribution on the ion beam cross-section, and so on, and the ion implantation may be monitored real-timely. Furthermore, when numerous workpieces are implanted in sequence, the profile(s) of one or more initially implanted workpiece(s) may be to generate a reference for calibrating the ion implantation of the following workpieces.

Abstract: Initially, an ion beam is formed as an elongated shape incident on a wafer, where the shape has a length along a first axis longer than a diameter of the wafer, and a width along a second axis shorter than the diameter of the wafer. Then, a center of the wafer is moved along a scan path intersecting the ion beam at a movement velocity, and the wafer is rotated around at a rotation velocity simultaneously. During the simultaneous movement and rotation, the wafer is totally overlapped with the ion beam along the first axis when the wafer intersects with the ion beam, and the rotation velocity is at most a few times of the movement velocity. Both the movement velocity and the rotation velocity can be a constant or have a velocity profile relative to a position of the ion beam across the wafer.

Abstract: The present invention discloses a low temperature ion implantation by performing a heating process after the end of an implanting process and before the wafer is moved into the external environment. This invention actively raises wafer temperature at a time no later than implementation of the vacuum venting process, such that the condensed moisture induced by the temperature difference between a vacuum environment inside ion implanter and an external environment outside ion implanter is effectively minimized. The wafer can be heated at a loadlock, a robot for transferring wafer and/or an implantation chamber. The wafer can be heated by a gas, a liquid, a light and/or a heater embedded in a holder for holding the wafer.

Abstract: To select a scan distance to be used in scanning a wafer with an implant beam, a dose distribution along a first direction is calculated based on size or intensity of the implant beam and a scan distance. The scan distance is the distance measured in the first direction between a first path and a final path of the implant beam scanning the wafer along a second direction in multiple paths. A relative velocity profile along the second direction is determined based on the dose distribution. Dose uniformity on the wafer is calculated based on the wafer being scanned using the relative velocity profile and the determined dose distribution. The scan distance is adjusted and the preceding steps are repeated until the calculated dose uniformity meets one or more uniformity criteria.

Abstract: An ion implanter and a method for implanting a wafer are provided, wherein the method includes the following steps. First, a wafer has at least a first portion requiring a first doping density and a second portion requiring a second doping density is provided. The first doping density is larger than the second doping density. Thereafter, the first portion is scanned by an ion beam with a first scanning parameter value, and the second portion is scanned by the ion beam with a second scanning parameter value. The first scanning parameter value can be a first scan velocity, and the second scanning parameter value can be a second scan velocity different than the first scan velocity. Alternatively, the first scanning parameter value can be a first beam current, and the second scanning parameter value can be a second beam current different than the first beam current.

Abstract: Techniques for low temperature ion implantation are disclosed. After a wafer is cooled to a temperature lower than a temperature of an environment outside of a chamber where the wafer is implanted, the cooled wafer is implanted by projecting an ion beam on the cooled wafer with a temperature adjusting apparatus being operated to cool the wafer simultaneously. Hence, heat produced by the ion beam on the implanted wafer is essentially removed by the temperature adjusting apparatus. Then, after the majority of the implanting process is performed, the temperature adjusting apparatus is turned down or off. Hence, during the residual implanting process, heat produced by the ion beam on the implanted wafer at least partially increases the temperature of the implanted wafer so that, after the ion implantation process is finished, the wafer can be moved into the environment with no, or at least less, water condensation.

Abstract: An implanter is equipped with an ion beam current detector, a temperature sensor, a temperature controller and a cooling system to increase the ratio of a specific ion cluster in the ion source chamber of the implanter. Therefore, the implanting efficiency for a shallow ion implantation is increased consequently.

Abstract: An ion implantation method is provided. The method, before ion implanting, is to rotate the substrate by an angle and shift the scan path of the ion beam with an interlace pitch in the direction perpendicular to the scan direction and on the plane of the substrate. Therefore a plurality of interlaced and not overlapped ion implantation scan lines are formed on the surface of the substrate, so the method can enhance the uniformity of the dose of the ion implantation in the substrate.

Abstract: An ion implantation method is provided. The method, before ion implanting, is to rotate the substrate by an angle and shift the scan path of the ion beam with an interlace pitch in the direction perpendicular to the scan direction and on the plane of the substrate. Therefore a plurality of interlaced and not overlapped ion implantation scan lines are formed on the surface of the substrate, so the method can enhance the uniformity of the dose of the ion implantation in the substrate.

Abstract: An implanter is equipped with an ion beam current detector, a temperature sensor, a temperature controller and a cooling system to increase the ratio of a specific ion cluster in the ion source chamber of the implanter. Therefore, the implanting efficiency for a shallow ion implantation is increased consequently.

Abstract: To select a scan distance to be used in scanning a wafer with an implant beam, a dose distribution along a first direction is calculated based on size or intensity of the implant beam and a scan distance. The scan distance is the distance measured in the first direction between a first path and a final path of the implant beam scanning the wafer along a second direction in multiple paths. A relative velocity profile along the second direction is determined based on the dose distribution. Dose uniformity on the wafer is calculated based on the wafer being scanned using the relative velocity profile and the determined dose distribution. The scan distance is adjusted and the preceding steps are repeated until the calculated dose uniformity meets one or more uniformity criteria.