Patent Number: 
Section: claims

1. A particle beam target, comprising:a target body that receives coolant via a coolant inlet, the target body including a front side, a back side, and a lateral outer wall extending from the front side to the back side;a target cavity disposed in the target body configured such that a particle beam can be directed into the target cavity via a target window, the target cavity including a back inner wall, a lateral inner wall, and a cross-section bounded by the lateral inner wall, the back inner wall spaced from the back side relative to a lateral axis, and the lateral inner wall extending from the back inner wall toward the front side generally along the direction of the lateral axis;a plurality of parallel grooves formed in the back side, each groove including a first groove end and a second groove end and running along a transverse direction from the first groove end to the second groove end, the transverse direction being orthogonal to the lateral axis;a plurality of peripheral bores extending through the target body from the plurality of grooves toward the front side, the peripheral bores arranged to circumscribe the target cavity cross-section in proximity to the lateral inner wall, wherein each groove fluidly communicates with at least one peripheral bore at the first groove end and at least one other peripheral bore at the second groove end; anda plurality of radial outflow bores extending in respective radial directions relative to the lateral axis from the plurality of peripheral bores to the lateral outer wall, each radial outflow bore fluidly communicating with at least one of the peripheral bores,wherein the target body defines a plurality of separate liquid coolant flow paths, each liquid coolant flow path running from a respective groove to at least one of the first groove end and the second groove end of the groove, through at least one peripheral bore, and through at least one radial outflow bore to the lateral outer wall. 2. The particle beam target of claim 1, further comprising a target material inlet bore extending through the target body and into fluid communication with the target cavity. 3. The particle beam target of claim 2, wherein the target cavity has an inlet pocket formed in the lateral inner wall and circumscribing the target material inlet bore. 4. The particle beam target of claim 3, wherein the inlet pocket has a lateral dimension running in a direction generally toward the front side and a width transverse to the lateral dimension, and the width decreases along the lateral dimension in a direction away from the target material inlet bore. 5. The particle beam target of claim 3, wherein the inlet pocket has a lateral dimension running in a direction generally toward the front side and a width transverse to the lateral dimension, and the lateral dimension is elongated relative to the width. 6. The particle beam target of claim 1, further comprising a target material outlet bore extending radially through the target body from the target cavity to the lateral outer wall. 7. The particle beam target of claim 6, wherein the target cavity has an outlet pocket formed in the lateral inner wall and circumscribing the target material outlet bore. 8. The particle beam target of claim 1, wherein at least one of the plurality of parallel grooves fluidly communicates with more than one peripheral bore at the first groove end and more than one other peripheral bore at the second groove end, and the number of grooves is less than half of the number of peripheral bores. 9. The particle beam target of claim 1, wherein at least one of the plurality of radial outflow bores fluidly communicates with more than one peripheral bore, and the number of radial outflow bores is less than the number of peripheral bores. 10. The particle beam target of claim 1, wherein the cross-sectional flow area of each peripheral bore is less than the cross-sectional flow area of each radial outflow bore. 11. The particle beam target of claim 1, wherein each groove has a cross-sectional area defined by a width of the groove in the transverse direction and a height of the groove in a direction orthogonal to the transverse direction, and the height of the groove ranges from 0.01 inch to 0.125 inch. 12. The particle beam target of claim 1, wherein the target body includes a back portion disposed between the back inner wall and at least a majority of the plurality of grooves, and the back portion has a thickness along the lateral axis ranging from 0.002 inch to 0.5 inch. 13. The particle beam target of claim 1, wherein each groove is separated from at least one other adjacent groove by a groove wall, and the groove wall has a thickness between the adjacent grooves ranging from 0.002 inch to 0.125 inch. 14. The particle beam target of claim 1, wherein the target body includes an annular portion disposed between the lateral inner wall and the plurality of peripheral bores, and the annular portion has a thickness in a radial dimension relative to the lateral axis ranging from 0.002 inch to 0.5 inch. 15. The particle beam target of claim 1, wherein the plurality of radial outflow bores are located closer to the front side than to the back side. 16. The particle beam target of claim 1, wherein the plurality of radial outflow bores are located at a distance from the front side along the lateral axis ranging from 0.01 inch to 0.5 inch. 17. The particle beam target of claim 1, wherein the target cavity has a depth along the lateral axis, and the plurality of peripheral bores extend from the plurality of grooves along at least a majority of the depth. 18. The particle beam target of claim 1, wherein each peripheral bore has a diameter ranging from 0.01 inch to 0.25 inch. 19. The particle beam target of claim 1, wherein the plurality of peripheral bores extend in a direction parallel to the lateral inner wall. 20. The particle beam target of claim 1, wherein the plurality of peripheral bores include a first set of peripheral bores communicating with the first groove ends of the respective grooves and a second set of peripheral bores communicating with the second groove ends of the respective grooves, and each peripheral bore is spaced from an adjacent peripheral bore in the same first or second set by a distance ranging from 0.002 inch to 0.125 inch. 21. The particle beam target of claim 1, further comprising a coolant inlet body abutting the back side and covering the plurality of peripheral bores, the coolant inlet body including an elongated slot fluidly communicating with each of the grooves, wherein the coolant inlet body defines a liquid coolant inlet flow path running through the elongated slot and into each of the grooves such that the liquid coolant inlet flow path branches into each of the liquid coolant flow paths, and each liquid coolant flow path is divided into a first liquid coolant flow path running to the first groove end and a second liquid coolant flow path running to the second groove end. 22. The particle beam target of claim 21, wherein the elongated slot is positioned at a point over each groove equidistant to the first groove end and to the second groove end of the groove, and the coolant flow in the liquid coolant flow path for the respective groove is divided approximately equally into the first liquid coolant flow path and the second liquid coolant flow path. 23. The particle beam target of claim 21, wherein the elongated slot has a cross-sectional flow area defined by a length along which the slot is elongated and a width orthogonal to the length, and the width is non-uniform such that the coolant flow rate into at least one of the plurality of grooves is different than the coolant flow rate into at least one other groove. 24. A particle beam target, comprising:a target body that receives coolant via a coolant inlet, the target body including a front side, a back side, and a lateral outer wall extending from the front side to the back side;a target cavity disposed in the target body configured such that a particle beam can be directed into the target cavity via a target window, the target cavity bounded by a lateral inner wall of the target body, the lateral inner wall disposed about a lateral axis and extending from a target cavity opening at the front side toward the back side;a channel formed at the front side and circumscribing the target cavity opening;a plurality of peripheral bores extending through the target body from the back side toward the front side, the peripheral bores circumscribing the target cavity in proximity to the lateral inner wall, wherein the peripheral bores are arranged along a peripheral bore perimeter at a radial distance between the target cavity and the channel relative to the lateral axis; anda plurality of radial outflow bores extending in respective radial directions relative to the lateral axis from the plurality of peripheral bores to the lateral outer wall, each radial outflow bore fluidly communicating with at least one of the peripheral bores, wherein the target body defines a plurality of separate liquid coolant flow paths, each liquid coolant flow path running from the back side of the target body, through at least one peripheral bore, and through at least one radial outflow bore to the lateral outer wall. 25. The particle beam target of claim 24, further comprising a plurality of parallel grooves formed in the back side, each groove including a first groove end and a second groove end and running along a transverse direction from the first groove end to the second groove end, the transverse direction being orthogonal to the lateral axis, wherein each liquid coolant flow path running from a respective groove to at least one of the first groove end and the second groove end of the groove, through at least one peripheral bore, through at least one radial outflow bore, and to the lateral outer wall. 26. The particle beam target of claim 25, wherein at least one of the plurality of parallel grooves fluidly communicates with more than one peripheral bore at the first groove end and more than one other peripheral bore at the second groove end, and the number of grooves is less than half of the number of peripheral bores. 27. The particle beam target of claim 25, further comprising a coolant inlet body abutting the back side and covering the plurality of peripheral bores, the coolant inlet body including an elongated slot fluidly communicating with each of the grooves, wherein the coolant inlet body defines a liquid coolant inlet flow path running through the elongated slot and into each of the grooves such that the liquid coolant inlet flow path branches into each of the liquid coolant flow paths, and each liquid coolant flow path is divided into a first liquid coolant flow path running to the first groove end and a second liquid coolant flow path running to the second groove end. 28. The particle beam target of claim 24, wherein at least one of the plurality of radial outflow bores fluidly communicates with more than one peripheral bore, and the number of radial outflow bores is less than the number of peripheral bores. 29. The particle beam target of claim 24, wherein the target body includes an annular portion disposed between the lateral inner wall and the plurality of peripheral bores, and the annular portion has a thickness in a radial dimension relative to the lateral axis ranging from 0.002 inch to 0.5 inch. 30. The particle beam target of claim 24, wherein the plurality of radial outflow bores are located closer to the front side than to the back side. 31. The particle beam target of claim 24, wherein the target cavity has a depth along the lateral axis, and the plurality of peripheral bores extend from the plurality of grooves along at least a majority of the depth. 32. A particle beam target, comprising:a target body that receives coolant via a coolant inlet, the target body including a front side, a back side, and a lateral outer wall extending from the front side to the back side;a target cavity disposed in the target body configured such that a particle beam can be directed into the target cavity via a target window, the target cavity bounded by a lateral inner wall of the target body, the lateral inner wall disposed about a lateral axis and extending from a target cavity opening at the front side toward the back side;a plurality of peripheral bores extending through the target body from the back side toward the front side and circumscribing the target cavity, wherein the target body further includes an annular portion interposed between the lateral inner wall and the peripheral bores, and the annular portion has a radial thickness between the lateral inner wall and the peripheral bores ranging from 0.002 inch to 0.5 inch; anda plurality of radial outflow bores extending in respective radial directions relative to the lateral axis from the plurality of peripheral bores to the lateral outer wall, each radial outflow bore fluidly communicating with at least one of the peripheral bores, wherein the target body defines a plurality of separate liquid coolant flow paths, each liquid coolant flow path running from the back side of the target body, through at least one peripheral bore, and through at least one radial outflow bore to the lateral outer wall. 33. The particle beam target of claim 32, further comprising a plurality of parallel grooves formed in the back side, each groove including a first groove end and a second groove end and running along a transverse direction from the first groove end to the second groove end, the transverse direction being orthogonal to the lateral axis, wherein each liquid coolant flow path running from a respective groove to at least one of the first groove end and the second groove end of the groove, through at least one peripheral bore, through at least one radial outflow bore, and to the lateral outer wall. 34. The particle beam target of claim 33, wherein at least one of the plurality of parallel grooves fluidly communicates with more than one peripheral bore at the first groove end and more than one other peripheral bore at the second groove end, and the number of grooves is less than half of the number of peripheral bores. 35. The particle beam target of claim 33, further comprising a coolant inlet body abutting the back side and covering the plurality of peripheral bores, the coolant inlet body including an elongated slot fluidly communicating with each of the grooves, wherein the coolant inlet body defines a liquid coolant inlet flow path running through the elongated slot and into each of the grooves such that the liquid coolant inlet flow path branches into each of the liquid coolant flow paths, and each liquid coolant flow path is divided into a first liquid coolant flow path running to the first groove end and a second liquid coolant flow path running to the second groove end. 36. The particle beam target of claim 32, wherein at least one of the plurality of radial outflow bores fluidly communicates with more than one peripheral bore, and the number of radial outflow bores is less than the number of peripheral bores. 37. The particle beam target of claim 32, wherein the plurality of radial outflow bores are located closer to the front side than to the back side. 38. The particle beam target of claim 33, wherein the target cavity has a depth along the lateral axis, and the plurality of peripheral bores extend from the plurality of parallel grooves along at least a majority of the depth. 39. A particle beam target, comprising:a target body that receives coolant via a coolant inlet, the target body including a front side, a back side, and a lateral outer wall extending from the front side to the back side;a target cavity disposed in the target body and bounded by a lateral inner wall of the target body, the lateral inner wall disposed about a lateral axis and extending from a target cavity opening at the front side toward the back side;a target window disposed at the front side and covering the target cavity opening;a plurality of peripheral bores extending through the target body from the back side toward the front side, the peripheral bores circumscribing the target cavity in proximity to the lateral inner wall, wherein the peripheral bores are arranged along a peripheral bore perimeter at a radial distance between the target cavity and an outer perimeter of the target window relative to the lateral axis; anda plurality of radial outflow bores extending in respective radial directions relative to the lateral axis from the plurality of peripheral bores to the lateral outer wall, each radial outflow bore fluidly communicating with at least one of the peripheral bores, wherein the target body defines a plurality of separate liquid coolant flow paths, each liquid coolant flow path running from the back side of the target body, through at least one peripheral bore, and through at least one radial outflow bore to the lateral outer wall. 40. The particle beam target of claim 39, further comprising a plurality of parallel grooves formed in the back side, each groove including a first groove end and a second groove end and running along a transverse direction from the first groove end to the second groove end, the transverse direction being orthogonal to the lateral axis, wherein each liquid coolant flow path running from a respective groove to at least one of the first groove end and the second groove end of the groove, through at least one peripheral bore, through at least one radial outflow bore, and to the lateral outer wall. 41. The particle beam target of claim 40, wherein at least one of the plurality of grooves fluidly communicates with more than one peripheral bore at the first groove end and more than one other peripheral bore at the second groove end, and the number of grooves is less than half of the number of peripheral bores. 42. The particle beam target of claim 40, further comprising a coolant inlet body abutting the back side and covering the plurality of peripheral bores, the coolant inlet body including an elongated slot fluidly communicating with each of the grooves, wherein the coolant inlet body defines a liquid coolant inlet flow path running through the elongated slot and into each of the grooves such that the liquid coolant inlet flow path branches into each of the liquid coolant flow paths, and each liquid coolant flow path is divided into a first liquid coolant flow path running to the first groove end and a second liquid coolant flow path running to the second groove end. 43. The particle beam target of claim 39, wherein at least one of the plurality of radial outflow bores fluidly communicates with more than one peripheral bore, and the number of radial outflow bores is less than the number of peripheral bores. 44. The particle beam target of claim 39, wherein the target body includes an annular portion disposed between the lateral inner wall and the plurality of peripheral bores, and the annular portion has a thickness in a radial dimension relative to the lateral axis ranging from 0.002 inch to 0.5 inch. 45. The particle beam target of claim 39, wherein the plurality of radial outflow bores are located closer to the front side than to the back side. 46. The particle beam target of claim 40, wherein the target cavity has a depth along the lateral axis, and the plurality of peripheral bores extend from the plurality of grooves along at least a majority of the depth.