Patent Number: 
Section: claims

1. In a method for performing charged-particle-beam (CPB) projection-exposure including the steps of dividing a pattern, to be projection-exposed onto a sensitive substrate, into multiple exposure units each defining a respective portion of the pattern; sequentially illuminating the exposure units with a charged-particle (CP) illumination beam to form a respective CP patterned beam; and projecting the patterned beam onto a sensitive substrate to form images of the exposure units at respective locations on the substrate at which the images of the exposure units are stitched together to form an image of the pattern on the substrate, a method for projection-exposing an exposure unit requiring more than one exposure shot, comprising: (a) with respect to any exposure unit defining a feature requiring two separate exposure shots to fully transfer the feature to the substrate, dividing each of such exposure units into first and second complementary exposure units each defining respective feature portions;  (b) defining boundaries around each first complementary exposure unit, and boundaries around each second complementary exposure unit, wherein the boundaries around the first complementary exposure units do not cross over the respective feature portions defined by the first complementary exposure units, and the boundaries around the second complementary exposure units do not cross over the respective feature portions defined by the second complementary exposure units, thereby causing the boundaries around the second complementary exposure units to be shifted relative to the boundaries around the first complementary exposure units; and  (c) projection-exposing the first complementary exposure units and the second complementary exposure units onto respective locations on the substrate such that, when projection-exposing a second complementary exposure unit on an image of a respective first complementary exposure unit, the boundaries around the second complementary exposure unit are shifted relative to the boundaries around the respective first complementary exposure unit. 2. The method of  claim 1 , wherein, in step (b), the first and second complementary exposure units are defined on at least one stencil reticle. claim 1 3. A segmented reticle for use in charged-particle-beam microlithography, the reticle comprising: (a) multiple exposure units each defining a respective portion of a pattern to be projection-exposed onto a sensitive substrate;  (b) at least one exposure unit defining a feature requiring two separate exposures to fully transfer the feature to the substrate, said exposure unit being divided into first and second complementary exposure units each defining respective feature portions;  (c) each first complementary exposure unit being surrounded by respective boundaries, and each second complementary exposure unit being surrounded by respective boundaries, wherein the boundaries around the first complementary exposure units do not cross over the respective feature portions defined by the first complementary exposure units, and the boundaries around the second complementary exposure units do not cross over the respective feature portions defined by the second complementary exposure units, thereby causing the boundaries around the second complementary exposure units to be shifted relative to the boundaries around the first complementary exposure units whenever the feature portions defined by the second complementary exposure unit are placed in registration with the feature portions defined by the respective first complementary exposure units. 4. The reticle of  claim 3 , configured as a stencil reticle. claim 3 5. A charged-particle-beam microlithographic projection-exposure apparatus, comprising: (a) a substrate stage on which a sensitive substrate is mounted for CPB projection-exposure of the substrate;  (b) a reticle according to  claim 3 ;  claim 3 (c) a reticle stage on which the reticle is mounted;  (d) an illumination-optical system situated upstream of the reticle stage, the illumination-optical system being configured to sequentially illuminate the exposure units of the reticle with a CP illumination beam; and  (e) a projection-optical system situated between the reticle stage and the substrate stage, the projection-optical system being configured to project, via a patterned beam propagating downstream of the reticle on the reticle stage, an image of the illuminated exposure unit onto a corresponding location on the sensitive substrate so as to stitch together the exposure-unit images and form an image of the pattern on the substrate. 6. The apparatus of  claim 5 , wherein the reticle is a stencil reticle. claim 5 7. The apparatus of  claim 5 , wherein the reticle comprises a first reticle portion defining the first complementary exposure units and a second reticle portion defining the second complementary exposure units. claim 5 8. The apparatus of  claim 7 , wherein the first and second reticle portions are located on separate reticles. claim 7 9. A semiconductor-fabrication process, comprising the steps of: (a) preparing a wafer;  (b) processing the wafer; and  (c) assembling devices formed on the wafer during steps a and (b), wherein step (b) comprises a method for performing projection microlithography as recited in  claim 1 .  claim 1 10. A semiconductor-fabrication process, comprising the steps of: (a) preparing a wafer;  (b) processing the wafer; and  (c) assembling devices formed on the wafer during steps a and (b), wherein step (b) comprises the steps of (i) applying a resist to the wafer; (ii) exposing the resist; developing the resist; and (iv) annealing the resist; and step (ii) comprises providing a charged-particle-beam projection-exposure apparatus as recited in  claim 5 ; and using the charged-particle-beam projection-exposure apparatus to expose the resist with the pattern defined on the reticle.  claim 5 11. A semiconductor device produced by the method of  claim 10 . claim 10