Patent Number: 
Section: claims

1. An ion implanter system, the system comprising:an ion beam generator for generating an ion beam;a platen;a first test wafer disposed on the platen toward which the ion beam is directed;a second test wafer disposed on the platen toward which the ion beam is directed along a wall of at least one template, the at least one template positioned adjacent an ion beam path, each template having a template surface that impedes a motion of an ion in the ion beam in response to the ion impacting the template surface, wherein the ion impacts the template surface in the case that a trajectory of the ion varies from an optimum trajectory by at least a pre-determined maximum variance angle and wherein the ion impacts the second test wafer in the case that the trajectory of the ion varies from the optimum trajectory by less than the pre-determined maximum variance angle; andmeans for determining, using the at least one template and the first and second test wafers, whether an ion beam trajectory varies from the optimum trajectory by at least the pre-determined maximum variance angle to monitor an integrity of the ion beam, wherein the means for determining measures a difference between a first number of ions that impact the first test wafer and a second number of ions that impact the second test wafer to determine whether the ion beam trajectory varies from the optimum trajectory by at least the pre-determined maximum variance angle. 2. The system of claim 1, wherein the template surface undergoes a change in response to the impacting by the ion and wherein the means for determining measures the change in the template surface to determine whether the ion beam trajectory varies from the optimum trajectory by at least the pre-determined maximum variance angle. 3. The system of claim 1, wherein the at least one template includes an opening having a template opening width and a template wall having a template wall depth, and wherein an aspect ratio of the template opening width to the template wall depth corresponds to the pre-determined maximum variance angle. 4. The system of claim 3, wherein the at least one template includes a plurality of templates, wherein the aspect ratio of at least one template differs from the aspect ratio of at least one other template. 5. The system of claim 1, wherein the at least one template comprises at least two stacked templates oriented with an edge of the template wall of one template substantially perpendicular to the edge of the template wall of at least one other template. 6. The system of claim 1, wherein at least a portion of the template surface is at least one of a photoresist, an oxide and a nitride hard mask. 7. The system of claim 1, further comprising means for determining an adjustment of the ion beam based on an input from the means for determining. 8. A system for monitoring an integrity of an ion beam, the system comprising:a platen;a first test wafer disposed on the platen toward which an ion beam is directed;a second test wafer disposed on the platen toward which the ion beam is directed along a wall of at least one template, the at least one template positioned adjacent an ion beam path, each template having a template surface that impedes a motion of an ion wherein the ion impacts the template wall in the case that a trajectory of the ion varies from an optimum trajectory by at least a pre-determined maximum variance angle and wherein the ion impacts the second test wafer in the case that the trajectory of the ion varies from the optimum trajectory by less than the pre-determined maximum variance angle; andmeans for determining, using the at least one template and the first and second test wafers, whether an ion beam trajectory varies from the optimum trajectory by at least the pre-determined maximum variance angle to monitor the integrity of the ion beam, wherein the means for determining measures a difference between a first number of ions that impact the first test wafer and a second number of ions that impact the second test wafer to determine whether the ion beam trajectory varies from the optimum trajectory by at least the pre-determined maximum variance angle. 9. The system of claim 8, wherein the template surface undergoes a change in response to the impacting by the ion and wherein means for determining measures the change in the template surface to determine whether the ion beam trajectory varies from the optimum trajectory by at least the pre-determined maximum variance angle. 10. The system of claim 8, wherein the at least one template includes an opening having a template opening width and a template wall having a template wall depth, and wherein an aspect ratio of the template opening width to the template wall depth corresponds to the maximum variance angle. 11. The system of claim 10, wherein the at least one template includes a plurality of templates, wherein the aspect ratio of at least one template differs from the aspect ratio of at least one other template. 12. The system of claim 8, wherein the at least one template comprises at least two stacked templates oriented with an edge of a template wall of one template substantially perpendicular to the edge of the template wall of at least one other template. 13. The system of claim 8, wherein at least a portion of the template surface is at least one of a photoresist, an oxide and a nitride hard mask. 14. The system of claim 8, further comprising means for determining an adjustment of the ion beam based on an input from the means for determining. 15. A method of monitoring angle integrity of an ion beam, the method comprising the steps of:transmitting an ion beam toward a first test wafer disposed on a platen;transmitting the ion beam adjacent to at least one template toward a second test wafer disposed on the platen along a wall of the template, the at least one template having a template surface that impedes a motion of an ion that varies from an optimum trajectory by at least a pre-determined maximum variance angle and wherein the ion impacts the second test wafer in the case that the trajectory of the ion varies from the optimum trajectory by less than the pre-determined maximum variance angle; anddetermining, using the at least one template and the first and second test wafers, whether an ion beam trajectory varies from the optimum trajectory by at least the pre-determined maximum variance angle to monitor angle integrity of the ion beam, wherein the determining step measures a difference between a first number of ions that impact the first test wafer and a second number of ions that impact the second test wafer to determine whether the ion beam trajectory varies from the optimum trajectory by at least the pre-determined maximum variance angle. 16. The method of claim 15, wherein the template surface undergoes a change in response to the impacting by the ion and wherein the determining step measures the change in the template surface to determine whether the ion beam trajectory varies from the optimum trajectory by at least the pre-determined maximum variance angle. 17. The method of claim 15, wherein the at least one template includes an opening having a template opening width and a template wall having a template wall depth, and wherein an aspect ratio of the template opening width to the template wall depth corresponds to the maximum variance angle. 18. The method of claim 17, wherein the at least one template includes a plurality of templates, wherein the aspect ratio of at least one template differs from the aspect ratio of at least one other template. 19. The method of claim 15, wherein the at least one template comprises at least two stacked templates oriented with an edge of the template wall of one template substantially perpendicular to the edge of the template wall of at least one other template. 20. The method of claim 15, wherein at least a portion of the template surface is at least one of a photoresist, an oxide and a nitride hard mask. 21. The method of claim 15, further comprising, determining an adjustment of the angle integrity of the ion beam based on the determining step. 22. A computer program product comprising a computer useable medium having computer readable program code embodied therein for determining the integrity of the angle of an ion beam generated by a ion implanter system and transmitted by the ion implanter system, the program product comprising:program code configured to control transmitting an ion beam toward a first test wafer disposed on a platen;program code configured to control transmitting the ion beam adjacent to at least one template along a wall of the template toward a second test wafer disposed on the platen, the at least one template having a surface that impedes a motion of an ion that varies from an optimum trajectory by at least a pre-determined maximum variance angle and wherein the ion impacts the second test wafer in the case that the trajectory of the ion varies from the optimum trajectory by less than the pre-determined maximum variance angle; andprogram code configured to determine, using the at least one template and the first and second test wafers, whether an ion beam trajectory varies from the optimum trajectory by at least the pre-determined maximum variance angle to monitor angle integrity of the ion beam, wherein the program code measures a difference between a first number of ions that impact the first test wafer and a second number of ions that impact the second test wafer to determine whether the ion beam trajectory varies from the optimum trajectory by at least the pre-determined maximum variance angle. 23. The program product of claim 22, wherein the template surface undergoes a change in response to the impacting by the ion and wherein the program code configured to determine measures the change in the template surface to determine whether an ion beam trajectory varies from the optimum trajectory by at least the pre-determined maximum variance angle. 24. The program product of claim 22, further comprising program code configured to determine an adjustment of the ion beam based on an input from the program code configured to determine.