Patent Number: 
Section: claims

1. A method for monitoring ion implantation, comprising:providing an ion beam and a workpiece;implanting said workpiece by said ion beam and generating a profile having a plurality of signals relevant to respectively a plurality of relative positions between said ion beam and said workpiece when said ion beam is scanned through said workpiece, wherein said profile comprises a higher portion, a gradual portion and a lower portion, a width of said ion beam is acquired by measuring a span of said gradual portion when a relative moving direction between said ion beam and said workpiece coincides with a minor axis of said ion beam and crosses a diameter of said workpiece, and a height of said ion beam is acquired by measuring a span of said gradual portion when said relative moving direction coincides with a major axis of said ion beam and crosses said diameter of said workpiece; andanalyzing said profile without referring to a pre-determined profile, wherein at least one of the following of said ion beam is monitored: a beam contour of said ion beam and a current distribution of said ion beam along an ion beam radial cross-section. 2. The method as claimed in claim 1, said profile being a current curve formed with a plurality of current values measured at said relative positions by a Faraday cup close to said workpiece. 3. The method as claimed in claim 1, said profile being a capacitance-related current curve formed with a plurality of capacitance-related current values measured at said relative positions by a capacitance meter electrically coupled with said workpiece. 4. The method as claimed in claim 1, further comprising scanning said workpiece by said ion beam along a plurality of first lines parallel to a specific diameter of said workpiece and along a plurality of second lines vertical to said specific diameter of said workpiece, such that a plurality of widths as a function of vertical position and a plurality of heights as a function of horizontal position are found respectively and then at least a contour and a center of a cross-section of said ion beam are converted accordingly. 5. The method as claimed in claim 1, further comprising converting said gradual portion to generate said current distribution of said ion beam along said ion beam radial cross-section. 6. The method as claimed in claim 1, further comprising using an N-points smoothing process to modify said profile, wherein N is a positive integer. 7. The method as claimed in claim 1, further comprising performing a correcting process to modify said profile when at least one specific said relative position has no proper measured said signal, said correcting process comprising at least one of following:generating a pseudo signal for each said specific relative position by extrapolating from at least two said signals measured at other said relative positions, and then generating said profile by both said signals and said pseudo signal; andgenerating a pseudo signal for each said specific relative position by interpolating from at least two said signals measured at other said relative positions, and then generating said profile by both said signals and said pseudo signal. 8. A method for monitoring ion implantation, comprising:(a) providing an ion beam and a plurality of workpieces;(b) implanting one or more said workpieces by said ion beam, wherein a profile having a plurality of signals relevant to respectively a plurality of relative positions between said ion beam and a said workpiece is generated when said ion beam is scanned through said workpiece, and said profile is analyzed without referring to a pre-determined profile for each implanted said workpieces, wherein each said profile comprises a higher portion, a gradual portion and a lower portion, wherein at least one of the following of said ion beam is monitored: a beam contour of said ion beam and a current distribution of said ion beam along an ion beam radial cross-section;(c) generating a reference being a function of said profiles corresponding to implanted said workpieces, wherein said reference is an average ion beam geometric message acquired by averaging one or more ion beam geometric messages of said profiles, and said ion beam geometric messages has at least one of the following: said ion beam contour, an ion beam height, an ion beam width and an ion beam center of said ion beam, wherein said ion beam width is acquired by measuring a span of said gradual portion of a said profile when a relative moving direction between said ion beam and said workpiece coincides with a minor axis of said ion beam and crosses a diameter of said workpiece, said ion beam height is acquired by measuring a span of said gradual portion of a said profile when said relative moving direction coincides with a major axis of said ion beam and crosses said diameter of said workpiece, and said ion beam contour and said ion beam center are converted from a plurality of said ion beam widths as a function of vertical position and a plurality of said ion beam heights as a function of horizontal position which are acquired by scanning said workpiece through said ion beam along a plurality of first lines parallel to a specific diameter of said workpiece and along a plurality of second lines vertical to said specific diameter of said workpiece;(d) implanting another one of said workpieces by said ion beam and generating an another profile when said ion beam is scanned through said another one of said workpieces, wherein said another profile having a plurality of signals relevant to respectively a plurality of relative positions between said ion beam and said another one of said workpieces, wherein said another profile comprises a higher portion, a gradual portion and a lower portion;(e) analyzing said another profile without referring to said pre-determined profile to generate an analyzed result, wherein at least one of the following of said ion beam is monitored: said beam contour of said ion beam and said current distribution of said ion beam along said ion beam radial cross-section; and(f) comparing said analyzed result of said another profile with said reference. 9. The method as claimed in claim 8, further comprising one or more of the following:repeating step (d), step (e) and step (f) in sequence until all said workpieces are implanted by said ion beam;tuning said ion beam whenever a difference between said analyzed result and said reference is un-acceptable, wherein said reference is updated by performing step (b) and step (c) again after said ion beam being tuned and before step (d), step (e) and step (f) being repeated in sequence for at least a said workpiece not yet implanted;tuning one or more ion implantation parameters whenever a difference between said analyzed result and said reference is un-acceptable, wherein said reference is updated by performing step (b) and step (c) again after one or more ion implantation parameters being adjusted and before step (d), step (e) and step (f) being repeated in sequence for at least a said workpiece not yet implanted, wherein said implantation parameters comprise: an ion beam energy, an ion beam direction, an ion beam diverse, a position of a said workpiece being implanted by said ion beam, and an alignment between said ion beam and a said workpiece being implanted by said ion beam; andcomparing said reference with a measured result measured by using a profiler to measure said ion beam after step (c), wherein step (d), step (e) and step (f) are not processed when a difference between said reference and said measured result is un-acceptable. 10. The method as claimed in claim 8, wherein said reference is an average current distribution along said ion beam radial cross-section acquired by averaging one or more said current distributions where each is converted from a said gradual value of a said profile. 11. The method as claimed in claim 9, further comprising one or more of the following:using a Faraday cup close to said workpiece to measure a plurality of current values at said relative positions, so that at least one said profile is formed as a current curve; andusing a capacitance meter electrically coupled with said workpiece to measure a plurality of capacitance-related current values at said relative positions, so that at least one said profile is formed as a capacitance-related current curve. 12. A method for monitoring ion implantation, comprising:providing an ion beam and a workpiece;implanting said workpiece by said ion beam and generating a profile having a plurality of signals relevant to respectively a plurality of relative positions between said ion beam and said workpiece when said ion beam is scanned through said workpiece, wherein said profile comprises a higher portion, a gradual portion and a lower portion;analyzing said profile without referring to a pre-determined profile, wherein at least one of the following of said ion beam is monitored: a beam contour of said ion beam and a current distribution of said ion beam along an ion beam radial cross-section; andscanning said workpiece by said ion beam along a plurality of first lines parallel to a specific diameter of said workpiece and along a plurality of second lines vertical to said specific diameter of said workpiece, such that a plurality of widths as a function of vertical position and a plurality of heights as a function of horizontal position are found respectively and then at least a contour and a center of a cross-section of said ion beam are converted accordingly. 13. The method as claimed in claim 12, said profile being a current curve formed with a plurality of current values measured at said relative positions by a Faraday cup close to said workpiece. 14. The method as claimed in claim 12, said profile being a capacitance-related current curve formed with a plurality of capacitance-related current values measured at said relative positions by a capacitance meter electrically coupled with said workpiece. 15. The method as claimed in claim 12, wherein a width of said ion beam is acquired by measuring a span of said gradual portion when a relative moving direction between said ion beam and said workpiece coincides with a minor axis of said ion beam and crosses a diameter of said workpiece, and a height of said ion beam is acquired by measuring a span of said gradual portion when said relative moving direction coincides with a major axis of said ion beam and crosses said diameter of said workpiece. 16. The method as claimed in claim 12, further comprising converting said gradual portion to generate said current distribution of said ion beam along said ion beam radial cross-section. 17. The method as claimed in claim 12, further comprising using an N-points smoothing process to modify said profile, wherein N is a positive integer. 18. The method as claimed in claim 12, further comprising performing a correcting process to modify said profile when at least one specific said relative position has no proper measured said signal, said correcting process comprising at least one of following:generating a pseudo signal for each said specific relative position by extrapolating from at least two said signals measured at other said relative positions, and then generating said profile by both said signals and said pseudo signal; andgenerating a pseudo signal for each said specific relative position by interpolating from at least two said signals measured at other said relative positions, and then generating said profile by both said signals and said pseudo signal.