Patent Number: 
Section: claims

1. A chamber for exposing a workpiece to charged particles propagated along a path, the chamber comprising:a charged particle source configured to generate a stream of charged particles;a collimator configured to collimate and direct the stream of charged particles from the charged particle source along an axis of propagation;a beam digitizer configured to create temporally and spatially resolved digital flashes comprising groups including at least one charged particle by adjusting longitudinal spacing between the charged particles along the axis of propagation;a deflector configured to deflect said digital flashes transversely to the direction of propagation, the deflector in said path between the collimator and the deflector;an objective lens assembly configured to demagnify said digital flashes or one or more groups of said digital flashes, the deflector in said path between the beam digitizer and the objective lens assembly; anda workpiece stage configured to hold a workpiece, the objective lens assembly between the deflector and the workpiece stage. 2. The chamber of claim 1, wherein the chamber is adapted to direct the stream of charged particles accelerating at potentials between about 5 and 500 keV. 3. The chamber of claim 1, wherein the charged particles comprise ions. 4. The chamber of claim 3, wherein the ions are positively charged. 5. The chamber of claim 3, wherein the ions are negatively charged. 6. The chamber of claim 3, wherein the ions are singly charged. 7. The chamber of claim 3, wherein the ions are doubly charged. 8. The chamber of claim 1, wherein the charged particles comprise electrons. 9. The chamber of claim 1, wherein the charged particles comprise positrons. 10. The chamber of claim 1, wherein the charged particle source comprises a liquid metal ion source (LMIS). 11. The chamber of claim 1, wherein the charged particle source comprises a plasma ion source (PIS). 12. The chamber of claim 1, wherein the charged particle source comprises a volume plasma ion source (VPIS). 13. The chamber of claim 1, wherein the charged particle source comprises a gas field ionization source (GFIS). 14. The chamber of claim 1, wherein the charged particle source comprises a carbon nanotube field emitter. 15. The chamber of claim 1, wherein the charged particle source comprises a free electron laser. 16. The chamber of claim 1, wherein the charged particle source comprises a pulsed ablation ion source. 17. The chamber of claim 1, wherein the charged particle source comprises a magnetically confined plasma anode source (MAP). 18. The chamber of claim 1, wherein the charged particle source comprises a thermal field emission electron source (TFE). 19. The chamber of claim 1, wherein the charged particle source is configured to generate a plurality of charged particle species. 20. The chamber of claim 1, wherein the charged particle source is configured to output the stream at accelerating potentials between about 5 and 30 keV. 21. The chamber of claim 1, wherein the charged particle source is configured to provide a current density of about 1×105 A/cm2 over an approximately 10 nm spot size measured at a workpiece held be the workpiece stage. 22. The chamber of claim 1, wherein the collimator comprises a lens. 23. The chamber of claim 1, wherein the collimator comprises reflective optics. 24. The chamber of claim 1, wherein the collimator comprises a lens and reflective optics. 25. The chamber of claim 1, wherein the collimator comprises two reflective optical elements. 26. The chamber of claim 1, wherein the collimator comprises a plurality of lenses. 27. The chamber of claim 1, wherein the collimator is configured to collimate the stream of charged particles. 28. The chamber of claim 1, wherein the collimator is configured to de-magnify the stream of charged particles to a Gaussian beam having less than about 1 μm full width half max diameter spot size. 29. The chamber of claim 1, wherein the collimator is configured to de-magnify the stream of charged particles to a Gaussian beam having a spot size less than about 100 nm full width half max diameter. 30. The chamber of claim 1, wherein the collimator is configured to de-magnify the stream of charged particles to a Gaussian beam having a spot size less than about 10 nm full width half max diameter. 31. The chamber of claim 1, further comprising a mass separator including a mass separator aperture plate, the mass separator in said path between the collimator and the beam digitizer and configured to deflect selected charged particle species into the mass separator aperture plate. 32. The chamber of claim 31, wherein the mass separator comprises reflective optics. 33. The chamber of claim 31, wherein the mass separator comprises an ExB Lens. 34. The chamber of claim 31, wherein the mass separator comprises a Wein filter. 35. The chamber of claim 1, further comprising a beam blanker configured to blank or compress the stream of charged particles or to both black and compress the stream of charged particles, wherein the beam digitizer is disposed in said path between the beam blanker and the deflector. 36. The chamber of claim 1, wherein the beam digitizer comprises a beam buncher. 37. The chamber of claim 36, wherein the beam buncher is configured to apply electromagnetic radiation having a frequency between about 1 MHz and 100 GHz. 38. The chamber of claim 36, wherein the beam buncher is configured to apply electromagnetic radiation having two or more resonant frequencies between about 1 MHz and 25 GHz. 39. The chamber of claim 36, wherein the beam buncher is configured to apply electromagnetic radiation and is configured to modulate an amplitude of the electromagnetic radiation. 40. The chamber of claim 36, wherein the beam buncher is configured to apply electromagnetic radiation and is configured to modulate a frequency of the electromagnetic radiation. 41. The chamber of claim 36, wherein the beam buncher comprises a series of electrodes, the beam buncher electrodes configured to be modulated by a voltage at a radio frequency (RF). 42. The chamber of claim 36, wherein the beam buncher is configured to apply electromagnetic radiation and wherein a mean velocity of the stream of charged particles is substantially similar to the frequency of the electromagnetic radiation. 43. The chamber of claim 36, wherein the beam buncher comprises a helical coil configured to be modulated by a voltage at a radio frequency (RF). 44. The chamber of claim 36, wherein the beam buncher is configured to alter the relative velocity of the particles thereby forming groups of said digital flashes, said groups forming a digital beam. 45. The chamber of claim 36, wherein the beam buncher is configured to apply an electric field configured to longitudinally compress or converge said charged particles into said digital flashes, said flashes forming a digital beam. 46. The chamber of claim 45, wherein an average velocity of the digital beam is between about 1×104 meters/second and 3×108 meters/second. 47. The chamber of claim 1, wherein the beam digitizer comprises a blanker configured to blank the stream of charged particles. 48. The chamber of claim 1, wherein the beam digitizer is configured to modulate an on/off state of the charged particle source so as to blank the stream of charged particles. 49. The chamber of claim 1, wherein the beam digitizer is configured to apply electromagnetic radiation configured to blank the stream of charged particles. 50. The chamber of claim 1, wherein the beam digitizer comprises a plasma beat wave modulator configured to blank the stream of charged particles. 51. The chamber of claim 1, wherein the beam digitizer comprises a space charge wake field modulator configured to blank the stream of charged particles. 52. The chamber of claim 1, wherein the beam digitizer comprises a resonant absorption space charge wake field modulator configured to blank the stream of charged particles. 53. The chamber of claim 1, wherein the beam digitizer comprises a generalized phased contrast modulator configured to blank the stream of charged particles. 54. The chamber of claim 1, wherein the beam digitizer comprises a pulsed incident neutralizing beam modulator configured to blank the stream of charged particles. 55. The chamber of claim 1, wherein the beam digitizer comprises a pulsed laser beam modulator configured to blank the stream of charged particles. 56. The chamber of claim 1, wherein the beam digitizer comprises a Bradbury-Nielson Gate (BNG) particle beam modulation device configured to blank the stream of charged particles. 57. The chamber of claim 1, wherein the beam digitizer is configured to create a digital beam comprising between about 1 and 7,000,000 charged particles per digital flash. 58. The chamber of claim 1, wherein the beam digitizer is configured to create a digital beam comprising between about 1 and 100,000 charged particles per digital flash. 59. The chamber of claim 1, wherein the beam digitizer is configured to create a digital beam comprising between about 1 and 10,000 charged particles per digital flash. 60. The chamber of claim 1, wherein the beam digitizer is configured to create a digital beam comprising between about 1 and 5,000 charged particles per digital flash. 61. The chamber of claim 1, wherein the beam digitizer is configured to create periods between pairs of said digital flashes of a digital beam that are directly adjacent of between about 1 nm and 9.99 meters of digital beam travel. 62. The chamber of claim 1, wherein the beam digitizer is configured to create periods between pairs of said digital flashes of a digital beam that are directly adjacent of between about 1 nm and 1 meter of digital beam travel. 63. The chamber of claim 1, wherein the beam digitizer is configured to create periods between pairs of said digital flashes of a digital beam that are directly adjacent of between about 1 nm and 10 cm of digital beam travel. 64. The chamber of claim 1, wherein the beam digitizer is configured to create periods between pairs of said digital flashes of a digital beam that are directly adjacent of between 1 nm and 1 cm of digital beam travel. 65. The chamber of claim 1, wherein the beam digitizer is configured to create periods between pairs of said digital flashes of a digital beam that are directly adjacent of between 1 nm and 100 μm of digital beam travel. 66. The chamber of claim 1, wherein the beam digitizer is configured to create periods between pairs of said digital flashes of a digital beam that are directly adjacent of between 1 nm and 10 μm of digital beam travel. 67. The chamber of claim 1, wherein the beam digitizer is configured to create periods between pairs of said digital flashes of a digital beam that are directly adjacent of between 1 nm and 1 μm of digital beam travel. 68. The chamber of claim 1, wherein the beam digitizer is configured to create a space of between about 1 nm and 10 meters of beam travel between a pair of said digital flashes of a digital beam that are directly adjacent. 69. The chamber of claim 1, wherein the beam digitizer is configured to create a space of less than about 10 meters of beam travel between a pair of said digital flashes of a digital beam that are directly adjacent. 70. The chamber of claim 1, wherein the beam digitizer is configured to create a space of less than about 1 meter of beam travel between a pair of said digital flashes of a digital beam that are directly adjacent. 71. The chamber of claim 1, wherein the beam digitizer is configured to create a space of less than about 1 cm of beam travel between a pair of said digital flashes of a digital beam that are directly adjacent. 72. The chamber of claim 1, wherein the beam digitizer is configured to create a space of less than about 1 mm of beam travel between a pair of said digital flashes of a digital beam that are directly adjacent. 73. The chamber of claim 1, wherein the beam digitizer is configured to create a space of less than about 100 nm of beam travel between a pair of said digital flashes of a digital beam that are directly adjacent. 74. The chamber of claim 1, wherein the beam digitizer is configured to create a space of less than about 10 nm of beam travel between a pair of said digital flashes of a digital beam that are directly adjacent. 75. The chamber of claim 1, wherein the beam digitizer is configured to create a space of less than about 1 nm of beam travel between a pair of said digital flashes of a digital beam that are directly adjacent. 76. The chamber of claim 1, wherein the beam digitizer is configured to create a space between a pair of said digital flashes that are directly adjacent of between about 2 nm and 12 mm. 77. The chamber of claim 1, wherein the beam digitizer is configured to create variable spaces between one or more pairs of said digital flashes. 78. The chamber of claim 1, wherein spacing between one or more pairs of said digital flashes is substantially the same. 79. The chamber of claim 1, wherein spacing between adjacent said digital flashes is substantially harmonic. 80. The chamber of claim 1, wherein spacing between adjacent said digital flashes is substantially random. 81. The chamber of claim 1, wherein the digital flashes form a digital beam comprised of charged particle compression waves longitudinal to the axis of propagation. 82. The chamber of claim 1, wherein at least some of the digital flashes have a three-dimensionally Gaussian geometry at the workpiece stage. 83. The chamber of claim 1, wherein at least some of the digital flashes have a trapezoidal cross-section along the axis of propagation. 84. The chamber of claim 1, wherein the digital flashes are three-dimensional and have a geometric cross-section having the shape of a rectangle, triangle, circle, or square. 85. The chamber of claim 1, wherein a current density of at least some of the digital flashes is adjustable. 86. The chamber of claim 1, wherein the period between a pair of said digital flashes that are directly adjacent is adjustable. 87. The chamber of claim 1, wherein the space between a pair of digital flashes that are directly adjacent is adjustable. 88. The chamber of claim 1, wherein an address placement of said digital flashes is adjustable. 89. The chamber of claim 1, wherein the energy of individual digital flashes is adjustable. 90. The chamber of claim 1, wherein the size of individual digital flashes is adjustable. 91. The chamber of claim 1, wherein the deflector is configured to arrange individual digital flashes or a group of said digital flashes into a three-dimensional timespace. 92. The chamber of claim 1, wherein the deflector comprises an array of collimated deflection electrodes longitudinally disposed along the axis of propagation. 93. The chamber of claim 1, wherein the deflector is configured to deflect said digital flashes substantially perpendicularly to the axis of propagation. 94. The chamber of claim 1, wherein the deflector comprises a series of deflection electrode stages disposed longitudinally along the axis of propagation, wherein each deflection electrode stage comprises one or more electrodes. 95. The chamber of claim 94, wherein each deflection electrode stage comprises two or more electrodes. 96. The chamber of claim 94, wherein each deflection electrode stage comprises three or more electrodes. 97. The chamber of claim 94, wherein each deflection electrode stage comprises four or more electrodes. 98. The chamber of claim 94, wherein longitudinal positions of the deflection electrode stages are adjustable. 99. The chamber of claim 94, wherein the deflection electrode stages are configured to synchronize deflection of said digital flashes to create a distributed pattern of individual digital flashes, a group of said digital flashes, or an adjustable virtual digital stencil comprising a plurality of said digital flashes or groups of said digital flashes. 100. The chamber of claim 94, wherein potentials of each of the deflection electrode stages are configured to be synchronized with a mean velocity of the beam. 101. The chamber of claim 94, wherein potentials of each of the deflection electrode stages are configured to be harmonically synchronized with velocities of said digital flashes or groups of said digital flashes. 102. The chamber of claim 94, wherein the deflector comprises at least two deflection electrode stages and wherein every other deflection electrode stage is configured to displace a digital flash or groups of said digital flashes towards an intended trajectory. 103. The chamber of claim 94, wherein the deflector comprises at least three deflection electrode stages and wherein every third deflection electrode stage is configured to displace a digital flash or groups of said digital flashes towards an intended trajectory. 104. The chamber of claim 94, wherein the deflector comprises at least N deflection electrode stages and wherein every Nth deflection electrode stage is configured to displace a digital flash or groups of said digital flashes towards an intended trajectory. 105. The chamber of claim 94, wherein potentials of each of the deflection electrode stages are configured to be randomly synchronized with velocities of said digital flashes or groups of said digital flashes. 106. The chamber of claim 94, wherein potentials of each of the deflection electrode stages are configured to partially displace a digital flash or groups of said digital flashes towards an intended trajectory. 107. The chamber of claim 94, wherein potentials of one deflection electrode stage is configured to substantially fully displace a digital flash or groups of said digital flashes towards an intended trajectory. 108. The chamber of claim 94, wherein potentials of a plurality of deflection electrode stages are configured to substantially fully displace each said digital flash or groups of said digital flashes towards an intended trajectory. 109. The chamber of claim 94, wherein a phase of adjacent said digital flashes of a digital beam longitudinal to the axis is configured to be substantially equal and wherein spacing between the deflection electrode stages is configured to be synchronized with the phase. 110. The chamber of claim 94, wherein a phase of adjacent said digital flashes of a digital beam longitudinal to the axis is configured to be single harmonic and wherein spacing between the deflection electrode stages is configured to be synchronized with the phase. 111. The chamber of claim 94, wherein a phase of adjacent said digital flashes of a digital beam longitudinal to the axis is configured to be multiple harmonic and wherein spacing between the deflection electrode stages is configured to be synchronized with the phase. 112. The chamber of claim 94, wherein a phase of adjacent digital flashes of a digital beam longitudinal to the axis is configured to be random and wherein spacing between the deflection electrode stages is adapted to be synchronized with the phase. 113. The chamber of claim 94, wherein the deflector further comprises a digital feedback system. 114. The chamber of claim 94, wherein a field perimeter of deflection by the deflection electrode stages is defined as the minor deflection field and wherein a size of the field is dependent on the variable energy of the beam. 115. The chamber of claim 94, wherein a field perimeter of deflection by the deflection electrode stages is defined as the minor deflection field and is displaced transverse to the axis of propagation less than about 4 mm from the center of the axis of propagation. 116. The chamber of claim 94, wherein a field perimeter of deflection by the deflection electrode stages is defined as the minor deflection field and is displaced transverse to the axis of propagation less than about 2 mm from the center of the axis of propagation. 117. The chamber of claim 94, wherein a field perimeter of deflection by the deflection electrode stages is defined as the minor deflection field and is displaced transverse to the axis of propagation less than about 1 mm from the center of the axis of propagation. 118. The chamber of claim 94, wherein a field perimeter of deflection by the deflection electrode stages is defined as the minor deflection field and is displaced transverse to the axis of propagation less than about 100 μm from the center of the axis of propagation. 119. The chamber of claim 1, wherein the objective lens assembly is configured to demagnify, focus, and deflect individual digital flashes or groups of said digital flashes to expose a workpiece held by the workpiece stage to an adjustable virtual digital stencil. 120. The chamber of claim 1, wherein the objective lens assembly comprises an electromagnetic lens. 121. The chamber of claim 1, wherein the objective lens assembly comprises a plurality of deflection plates. 122. The chamber of claim 1, wherein the objective lens assembly comprises reflective optics. 123. The chamber of claim 1, wherein the objective lens assembly comprises a combination of reflective optics and a refractive lens. 124. The chamber of claim 1, wherein the objective lens assembly comprises a combination of reflective optics and deflection electrodes. 125. The chamber of claim 1, wherein the objective lens assembly comprises a combination of deflection electrodes and a refractive lens. 126. The chamber of claim 1, wherein the objective lens assembly comprises one or more deflection electrode stages. 127. The chamber of claim 126, wherein each deflection electrode stage of the objective lens assembly comprises at least one electrode. 128. The chamber of claim 1, wherein the objective lens assembly is configured to demagnify and focus a single one of said digital flashes or a group of said digital flashes by a factor of less than about 1000×. 129. The chamber of claim 1, wherein the objective lens assembly is configured to demagnify and focus a single one of said digital flashes or a group of said digital flashes by a factor of less than about 100×. 130. The chamber of claim 1, wherein the objective lens assembly is configured to demagnify and focus a single one of said digital flashes or a group of said digital flashes by a factor of less than about 10×. 131. The chamber of claim 1, wherein a field perimeter of deflection by the objective lens assembly is defined as the major deflection field and wherein a size of the field is dependent on the variable energy of the beam. 132. The chamber of claim 1, wherein a field perimeter of deflection by the objective lens assembly is defined as the major deflection field and is displaced transverse to the axis of propagation less than about 10 mm from the center of the axis of propagation. 133. The chamber of claim 1, wherein a field perimeter of deflection by the objective lens assembly is defined as the major deflection field and is displaced transverse to the axis of propagation less than about 4 mm from the center of the axis of propagation. 134. The chamber of claim 1, wherein a field perimeter of deflection by the objective lens assembly is defined as the major deflection field and is displaced transverse to the axis of propagation less than about 2 mm from the center of the axis of propagation. 135. The chamber of claim 1, wherein a field perimeter of deflection by the objective lens assembly is defined as the major deflection field and is displaced transverse to the axis of propagation less than about 1 mm from the center of the axis of propagation. 136. The chamber of claim 1, wherein a field perimeter of deflection by the objective lens assembly is defined as the major deflection field and is displaced transverse to the axis of propagation less than about 100 μm from the center of the axis of propagation. 137. The chamber of claim 1, wherein the workpiece stage is configured to move continuously over a dimension in X, Y, and Z axes. 138. The chamber of claim 1, wherein the workpiece stage is configured to move continuously over a dimension up to 600 mm in each direction perpendicular to the axis of propagation. 139. The chamber of claim 1, wherein the workpiece stage is configured to move continuously over a dimension up to 60 mm in each direction perpendicular the axis of propagation. 140. The chamber of claim 1, wherein the workpiece stage comprises a linear drive workpiece stage. 141. The chamber of claim 1, wherein the workpiece stage comprises an air bearing workpiece stage. 142. The chamber of claim 1, wherein the workpiece stage comprises an interferometer configured to determine a location of the workpiece stage on a horizontal plane. 143. The chamber of claim 1, wherein the workpiece stage comprises an interferometer configured to determine a location of the workpiece stage on a horizontal plane and on a vertical axis. 144. The chamber of claim 1, further comprising a workpiece stage control system configured to measure and adjust x, y, and z positions and yaw, pitch, and roll of the workpiece stage. 145. The chamber of claim 144, wherein the workpiece stage control system is configured to limit a motion of the workpiece stage. 146. The chamber of claim 144, wherein the workpiece stage control system is configured to limit a velocity of the workpiece stage. 147. The chamber of claim 144, wherein the workpiece stage control system is configured to limit a position of the workpiece stage. 148. The chamber of claim 144, wherein the workpiece stage control system is configured to limit a breakaway force of the workpiece stage. 149. The chamber of claim 144, wherein the workpiece stage control system is configured to limit a height of the workpiece stage. 150. The chamber of claim 144, wherein the workpiece stage control system is configured to limit a drag of the workpiece stage. 151. The chamber of claim 1, wherein the workpiece stage is configured to perform full motion writing (FMW) including continuous movement during exposing a workpiece held by the workpiece stage. 152. The chamber of claim 1, wherein the workpiece stage is configured to move without stopping for more than 5 nanoseconds during 0.5 seconds during exposing a workpiece held by the workpiece stage. 153. The chamber of claim 1, wherein the workpiece stage is configured to compensate for horizontal positions of at least one of said digital flashes, a group of said digital flashes, or an adaptable virtual digital stencil comprising a plurality of said digital flashes or groups of said digital flashes. 154. The chamber of claim 1, wherein the workpiece stage is configured to rotate a workpiece held by the workpiece stage during exposure of said workpiece at not greater than about 40,000 rpm. 155. The chamber of claim 1, wherein the workpiece stage is configured to electro-statically clamp a workpiece. 156. The chamber of claim 1, wherein the workpiece stage is configured to modify a temperature of a workpiece held by the workpiece stage. 157. The chamber of claim 1, further comprising a workpiece alignment system. 158. The chamber of claim 1, further comprising a detection system configured to detect time of flight of the digital flashes. 159. The chamber of claim 1, further comprising a registration sensor. 160. The chamber of claim 159, wherein the registration sensor is configured to detect emissions incident from a registration mark on the workpiece stage or on a workpiece held by the workpiece stage. 161. The chamber of claim 160, wherein the emissions comprise electrons. 162. The chamber of claim 160, wherein the emissions comprise secondary ions. 163. The chamber of claim 159, wherein the registration mark includes a moiré pattern. 164. The chamber of claim 159, wherein the registration sensor is configured to detect emissions from a plurality of registration marks on the workpiece stage or on a workpiece held by the workpiece stage. 165. The chamber of claim 159, wherein the registration sensor is configured to detect and process differential signals from a plurality of registration marks on the workpiece stage or on a workpiece held by the workpiece stage. 166. The chamber of claim 159, wherein the registration sensor is configured to globally detect emissions across the workpiece stage or across a workpiece held by the workpiece stage. 167. The chamber of claim 159, wherein the registration sensor is configured to locally detect emissions across portions of the workpiece stage or across a workpiece held by the workpiece stage. 168. The chamber of claim 159, wherein the registration sensor is configured to detect backscatter emissions from a workpiece stage or from a workpiece held by the workpiece stage. 169. The chamber of claim 159, wherein the registration sensor is configured to detect emissions from an edge of the workpiece stage or an edge of a workpiece held by the workpiece stage. 170. The chamber of claim 1, further comprising a height control system configured to measure a height of the workpiece stage. 171. The chamber of claim 170, wherein the height control system comprises a laser and a detector, the detector configured to receive light emitted from the laser and reflected by the workpiece stage or by a workpiece held by the workpiece stage. 172. The chamber of claim 170, wherein the height control system comprises a laser and a plurality of detectors, the plurality of detectors configured to receive light emitted from the lasers and reflected by the workpiece stage or by a workpiece held by the workpiece stage. 173. The chamber of claim 170, wherein the height control system is configured to compensate for variation in the measured height of the workpiece stage by adjusting an elevation of the workpiece stage. 174. The chamber of claim 173, wherein the height control system is configured to compensate for height variations of less than about 1 micron. 175. The chamber of claim 171, wherein the height control system comprises electrostatic clamps and piezoelectric devices. 176. The chamber of claim 1, wherein the workpiece stage is configured to hold a semiconductor wafer. 177. The chamber of claim 1, wherein the workpiece stage is configured to hold a semiconductor device. 178. The chamber of claim 1, wherein the workpiece stage is configured to hold a photomask. 179. The chamber of claim 1, wherein the workpiece stage is configured to hold a digital media disk. 180. A workpiece processing apparatus comprising:a loadlock chamber;the chamber of claim 1; anda processing chamber. 181. The apparatus of claim 180, wherein the processing chamber is selected from a group consisting of deposition, etch, and rapid thermal anneal chambers. 182. The apparatus of claim 180, comprising a plurality of processing chambers. 183. The apparatus of claim 180, further comprising a workpiece stage control system configured to detect positional accuracy information. 184. The apparatus of claim 183, further comprising a feedback system configured to adjust a parameter the digital flashes based on said detected positional accuracy information. 185. The apparatus of claim 183, wherein the workpiece stage control system is configured to correct for at least one of coma distortion, digital beam astigmatism, digital beam pure distortion, chromatic aberration, spherical aberration, and field curvature. 186. The apparatus of claim 180, further comprising an integrated pattern data and beam deflection correction system. 187. The apparatus of claim 180, further comprising a transport module configured to move workpieces within the apparatus. 188. The apparatus of claim 180, further comprising a workpiece prealigner. 189. The apparatus of claim 188, wherein the workpiece prealigner is configured to determine overlay parameters of workpiece alignment features. 190. The apparatus of claim 189, wherein the overlay parameters comprise x and y offset. 191. The apparatus of claim 189, wherein the overlay parameters comprise rotation. 192. The apparatus of claim 180, further comprising a particle detector. 193. The apparatus of claim 180, further comprising a temperature quenching station. 194. The apparatus of claim 180, further comprising system for indexing and identifying workpieces. 195. The apparatus of claim 180, further comprising a metrology station. 196. The apparatus of claim 195, wherein the metrology station comprises a secondary ion mass spectrometer (SIMS). 197. The apparatus of claim 195, wherein the metrology station comprises a scanning electron microscope (SEM). 198. The apparatus of claim 195, wherein the metrology station comprises a two-dimensional laser scanning imager. 199. The apparatus of claim 195, wherein the metrology station comprises a three-dimensional imaging laser radar (LADAR). 200. The apparatus of claim 195, wherein the metrology station comprises a thermal imager. 201. The apparatus of claim 195, wherein the metrology station comprises a millimeter wave imager. 202. The apparatus of claim 195, wherein the metrology station comprises a workpiece imager. 203. The apparatus of claim 195, wherein the metrology station comprises a camera. 204. The apparatus of claim 195, wherein the metrology station comprises energy dispersive spectrometry (EDS). 205. The apparatus of claim 195, wherein the metrology station comprises wavelength dispersive spectrometry (WDS). 206. The apparatus of claim 180, wherein the processing chamber comprises a temperature control system including automated control hardware and software. 207. The apparatus of claim 180, wherein the processing chamber comprises a pressure control system including automated control hardware and software. 208. The apparatus of claim 207, wherein the pressure control system is configured to control partial pressures of gas species in the processing chamber. 209. The apparatus of claim 180, wherein the loadlock chamber is configured to accept a front opening unified pod (FOUP). 210. The apparatus of claim 180, wherein the loadlock chamber is configured to simultaneously handle a plurality of workpieces. 211. The apparatus of claim 180, wherein the chamber is mounted on a vibration isolation system. 212. The apparatus of claim 211, wherein the vibration isolation system includes active damping. 213. The apparatus of claim 211, wherein the vibration isolation system includes passive damping. 214. The apparatus of claim 211, wherein the vibration isolation system includes active damping and passive damping. 215. The apparatus of claim 180, configured to process a workpiece from an initial state to a substantially finished state without removing said workpiece from the apparatus. 216. The apparatus of claim 215, wherein the initial state comprises a bare substrate. 217. The apparatus of claim 215, wherein the initial state comprises a substrate including a deposited oxide layer. 218. The apparatus of claim 215, wherein the initial state comprises a substrate including a resist material upon the surface. 219. The apparatus of claim 215, wherein the initial state comprises a substrate including a combination resist material upon the surface and deposited oxide layer. 220. The apparatus of claim 215, wherein the initial state comprises a substrate prepared with interactive coating of the workpiece surface. 221. The apparatus of claim 215, wherein the initial state comprises a substrate prepared with non-interactive coating of the workpiece surface. 222. The apparatus of claim 215, wherein the substantially finished state comprises one or more process layers. 223. The apparatus of claim 215, wherein the substantially finished state comprises one or more critical layers. 224. The apparatus of claim 215, wherein the substantially finished state comprises partial exposure of said workpiece to the beam. 225. The apparatus of claim 215, wherein the substantially finished state comprises one or more devices. 226. The apparatus of claim 215, wherein the substantially finished state comprises one or more devices ready for passivation. 227. The apparatus of claim 215, wherein the substantially finished state comprises a fully completed workpiece requiring no further process layers. 228. The apparatus of claim 215, wherein the initial state comprises a semiconductor wafer prior to forming layers that are part of a particular device. 229. The apparatus of claim 215, wherein the final state comprises said semiconductor wafer after forming said particular device. 230. A chamber for exposing a workpiece to charged particles, the chamber comprising:a charged particle source configured to generate a stream of charged particles;a collimator configured to collimate and direct the stream of charged particles from the charged particle source along an axis of propagation;a beam digitizer downstream of the collimator, the beam digitizer configured to create a digital beam comprising groups of at least one charged particle by adjusting longitudinal spacing between the charged particles along the axis;a deflector downstream of the beam digitizer configured to deflect the groups of charged particles; anda workpiece stage downstream of the deflector, the workpiece stage configured to hold the workpiece.