Patent Number: 
Section: claims

1. A method for configuring a reticle pattern to be defined on a reticle used for charged-particle-beam microlithography, comprising: identifying an element of the pattern destined for transfer-exposure to a region of a chip formed on a lithographic substrate, the pattern element having an initial configuration; and  reconfiguring the pattern element as defined on the reticle such that the profile at least partially offsets proximity effects that otherwise would be imparted to the pattern element, if the element were to be transfer-exposed in its initial configuration to the chip, by proximal elements of the pattern transfer-exposed to the same chip and by proximal elements located in an adjacent chip or chips on the substrate. 2. The method of  claim 1 , wherein the reconfigured pattern element is defined in one or more subfields of the reticle. claim 1 3. A method for configuring a reticle pattern to be defined on a reticle used for charged-particle-beam microlithography, comprising: identifying an element of the pattern destined for transfer-exposure to a region of a chip formed on a lithographic substrate, the pattern element having an initial configuration;  determining a net proximity effect that otherwise would be imparted to the pattern element, if the element were to be transfer-exposed in its initial configuration to the chip, by proximal elements of the pattern transfer-exposed to the same chip and by proximal elements located in one or more adjacent chips on the substrate; and  reconfiguring the element as defined on the reticle so as to offset the net proximity effect at least partially. 4. The method of  claim 3 , wherein the reconfigured pattern element is defined in one or more subfields of the reticle. claim 3 5. A method for configuring a reticle pattern to be defined on a reticle used for charged-particle-beam microlithography, comprising: identifying an element of the pattern destined for transfer-exposure to a region of a chip formed on a lithographic substrate, the pattern element having an initial configuration;  determining a net proximity effect that otherwise would be imparted to the pattern element, if the element were to be transfer-exposed in its initial configuration to the chip, by at least one proximal element of the pattern transfer-exposed to the same chip and by at least one proximal element located in one or more adjacent chips on the substrate;  calculating a profile change to be made to the pattern element, as defined on the reticle, that would offset the net proximity effect at least partially and cause the pattern element, when transfer-exposed to the substrate, to be substantially similar to a corresponding design-mandated profile for the element;  changing the profile of the pattern element according to the calculated profile change; and  defining the pattern element on the reticle according to the changed profile. 6. The method of  claim 5 , further comprising the steps: claim 5 determining a manner in which the pattern is to be divided, on the reticle, into subfields; and  defining the pattern element in at least one subfield. 7. A method for manufacturing a divided reticle for use in charged-particle-beam microlithography, comprising: dividing a pattern, to be defined on the reticle, into subfields each including a respective portion of the pattern;  identifying a pattern element destined for transfer-exposure to a region of a chip formed on a lithographic substrate, the pattern element having an initial configuration;  reconfiguring the pattern element so as to have a profile, as defined on the reticle, that at least partially offsets a net proximity effect that otherwise would be imparted to the pattern element, if the element were to be transfer-exposed in its initial configuration to the chip, by at least one proximal element of the pattern transfer-exposed to the same chip and by at least one proximal element located in one or more adjacent chips on the substrate;  defining the reconfigured pattern element in at least one subfield; and  fabricating the reticle to include the reconfigured pattern element. 8. A divided reticle, manufactured by the method as recited in  claim 7 . claim 7 9. A method for manufacturing a divided reticle for use in charged particle-beam microlithography, comprising: dividing a pattern, to be defined on the reticle, into subfields each including a respective portion of the pattern;  identifying a pattern element destined for transfer-exposure to a region of a chip formed on a lithographic substrate, the pattern element having an initial configuration;  determining a net proximity effect that otherwise would be imparted to the pattern element, if the element were to be transfer-exposed in its initial configuration to the chip, by at least one proximal element of the pattern transfer-exposed to the same chip and from proximal elements located in adjacent chips on the substrate;  reconfiguring the pattern element to have a profile that at least partially offsets the net proximity effect;  defining the reconfigured pattern element in at least one subfield; and  fabricating the reticle to include the reconfigured pattern element. 10. A divided reticle, manufactured by the method as recited in  claim 9 . claim 9 11. A method for manufacturing a divided reticle for use in charged-particle-beam microlithography, comprising: dividing a pattern, to be defined on the reticle, into subfields each including a respective portion of the pattern;  identifying a pattern element destined for transfer-exposure to a region of a chip formed on a lithographic substrate, the pattern element having an initial configuration;  determining a net proximity effect that otherwise would be imparted to the pattern element, if the element were to be transfer-exposed in its initial configuration to the chip, by at least one proximal element of the pattern transfer-exposed to the same chip and by proximal elements located in adjacent chips on the substrate;  calculating a reconfigured profile of the pattern element, as defined by the reticle, that would offset the net proximity effect at least partially and cause the pattern element, when transfer-exposed to the substrate, to be substantially similar to a corresponding design-mandated profile;  reconfiguring the pattern element according to the calculation;  defining the reconfigured pattern element in at least one subfield; and  fabricating the reticle to include the reconfigured pattern element. 12. A divided reticle, manufactured by the method as recited in  claim 11 . claim 11 13. A method for performing a microlithographic exposure using a charged particle beam, the method comprising: (a) providing a divided reticle as recited in  claim 9 , the reticle defining a pattern divided among multiple subfields;  claim 9 (b) directing a charged-particle illumination beam subfield-by-subfield through the reticle, to produce a corresponding patterned beam; and  (c) directing the patterned beam to a resist-coated lithographic substrate so as to imprint the pattern in multiple chips on the substrate. 14. The method of  claim 13 , wherein step (c) comprises imprinting the pattern in centrally located chips and in peripherally located chips on the substrate, the method further comprising the step of reducing variations in the imprinted profile of the pattern element in the peripherally located chips versus in the centrally located chips on the substrate by transfer-exposing portions, of peripheral chips that extend partially off the substrate, of such peripheral chips still remaining on the substrate. claim 13 15. The method of  claim 14 , wherein, with respect to the peripheral chips extending partially off the substrate, at least one respective subfield of the portions of such peripheral chips still remaining on the substrate is transfer-exposed. claim 14 16. A method for performing a microlithographic exposure using a charged particle beam, the method comprising: (a) providing a divided reticle as recited in  claim 10 , the reticle defining a pattern divided among multiple subfields;  claim 10 (b) directing a charged-particle illumination beam subfield-by-subfield through the reticle, to produce a corresponding patterned beam; and  (c) directing the patterned beam to a resist-coated lithographic substrate so as to imprint the pattern in multiple chips on the substrate. 17. The method of  claim 16 , wherein step (c) comprises imprinting the pattern in centrally located chips and in peripherally located chips on the substrate, the method further comprising the step of reducing variations in the imprinted profile of the pattern element in the peripherally located chips versus in the centrally located chips on the substrate by transfer-exposing portions, of peripheral chips that extend partially off the substrate, of such peripheral chips still remaining on the substrate. claim 16 18. The method of  claim 17 , wherein, with respect to the peripheral chips extending partially off the substrate, at least one respective subfield of the portions of such peripheral chips still remaining on the substrate is transfer-exposed. claim 17 19. A method for performing a microlithographic exposure using a charged particle beam, the method comprising: (a) providing a divided reticle as recited in  claim 12 , the reticle defining a pattern divided among multiple subfields;  claim 12 (b) directing a charged-particle illumination beam subfield-by-subfield through the reticle, to produce a corresponding patterned beam; and  (c) directing the patterned beam to a resist-coated lithographic substrate so as to imprint the pattern in multiple chips on the substrate. 20. The method of  claim 19 , wherein step (c) comprises imprinting the pattern in centrally located chips and in peripherally located chips on the substrate, the method further comprising the step of reducing variations in the imprinted profile of the pattern element in the peripherally located chips versus in the centrally located chips on the substrate by transfer-exposing portions, of peripheral chips that extend partially off the substrate, of such peripheral chips still remaining on the substrate. claim 19 21. The method of  claim 20 , wherein, with respect to the peripheral chips extending partially off the substrate, at least one respective subfield of the portions of such peripheral chips still remaining on the substrate is transfer-exposed. claim 20 22. A method for manufacturing a microelectronic device, comprising a microlithographic-exposure method as recited in  claim 13 . claim 13 23. A method for manufacturing a microelectronic device, comprising a microlithographic-exposure method as recited in  claim 16 . claim 16 24. A method for manufacturing a microelectronic device, comprising a microlithographic-exposure method as recited in  claim 19 . claim 19