Patent Number: 
Section: claims

1. A charged particle beam exposure system comprising: a charged particle beam emitting device which generates charged particle beams with which a substrate is irradiated, said charged particle beam emitting device generating the charged particle beams at an accelerating voltage which is lower than that at which an influence of a proximity effect occurs, the proximity effect being a phenomenon in which at least one of a secondary charged particle and a reflected charged particle which is produced from the surface of the substrate irradiated with the charged particle beams influences an exposure extent of a pattern which is adjacent to a pattern to be written;  an illumination optical system which adjusts a beam diameter of the charged particle beams so that a density of the charged particle beams is uniform;  a character aperture in which an aperture hole is formed in a shape corresponding to a desired pattern to be written;  a first deflector which deflects the charged particle beams by an electrostatic field so that the charged particle beams have a desired sectional shape and travel towards a desired aperture hole and which returns the charged particle beams passing through said aperture hole to an optical axis thereof;  a reducing projecting optical system which forms a multi-pole lens field so that the charged particle beams passing through said character aperture substantially reduce at the same demagnification both in X and Y directions when the optical axis extends in Z directions and form an image on the substrate without forming any crossover between said character aperture and the substrate; and  a second deflector which deflects the charged particle beams passing through said character aperture by means of an electrostatic field to scan the substrate with the charged particle beams. 2. A charged particle beam exposure system according to  claim 1 , wherein said reducing projecting optical system includes multi-pole lenses the number of which is N 1 , N 1  being a natural number of 3 or more. claim 1 3. A charged particle beam exposure according to  claim 2 , wherein said second deflector deflects the charged particle beams in the X directions and the charged particle beams in said Y directions independently of each other. claim 2 4. A charged particle beam exposure system according to  claim 3 , wherein said N 1  is 4. claim 3 5. A charged particle beam exposure system comprising: a charged particle beam emitting device which generates charged particle beams with which a substrate is irradiated, said charged particle beam emitting device generating the charged particle beams at an accelerating voltage which is lower than that at which an influence of a proximity effect occurs, the proximity effect being a phenomenon in which at least one of a secondary charged particle and a reflected charged particle which is produced from the surface of the substrate irradiated with the charged particle beams influences an exposure extent of a pattern which is adjacent to a pattern to be written;  an illumination optical system which adjusts a beam diameter of the charged particle beams so that a density of the charged particle beams is uniform;  a character aperture in which an aperture hole is formed in a shape corresponding to a desired pattern to be written;  a first deflector which deflects the charged particle beams by an electrostatic field so that the charged particle beams have a desired sectional shape and travel towards a desired aperture hole and which returns the charged particle beams passing through said aperture hole to an optical axis thereof;  a reducing projecting optical system which forms a multi-pole lens field so that the charged particle beams passing through said character aperture substantially reduce at the same demagnification both in X and Y directions when the optical axis extends in Z directions and form an image on the substrate without forming any crossover between said character aperture and the substrate,  wherein said reducing projecting optical system includes four multi-pole lenses; and  a second deflector which deflects the charged particle beams passing through said character aperture by means of an electrostatic field to scan the substrate with the charged particle beams,  wherein said second deflector deflects the charged particle beams in the X directions and the charged particle beams in said Y directions independently of each other, and said four multi-pole lenses are controlled to form first through fourth electrostatic fields so that said first through fourth electrostatic fields sequentially form a divergent electrostatic field, a divergent electrostatic field, a convergent electrostatic field and a divergent electrostatic field in one direction of the X and Y directions and so as to sequentially form a convergent electrostatic field, a convergent electrostatic field, a divergent electrostatic field and a convergent electrostatic field in the other direction of the X and Y directions. 6. A charged particle beam exposure system according to  claim 5 , wherein said second deflector includes a plurality of electrostatic deflectors. claim 5 7. A charged particle beam exposure system according to  claim 6 , wherein said second deflector superimposes an electrostatic deflection field on said multi-pole lens field to deflect the charged particle beams. claim 6 8. A charged particle beam exposure system according to  claim 7 , which further comprises a first main deflector which includes multi-pole electrodes, said first main deflector being provided between a second multi-pole lens and a third multi-pole lens of said first multi-pole lenses, claim 7 wherein said multi-pole lens is controlled to form first through fourth electrostatic fields so that said first through fourth electrostatic fields sequentially form a divergent electrostatic field, a divergent electrostatic field, a convergent electrostatic field and a divergent electrostatic field in the X directions and to sequentially form a convergent electrostatic field, a convergent electrostatic field, a divergent electrostatic field and a convergent electrostatic field in the Y directions,  said third multi-pole lens and said fourth multi-pole lens serve as a second main deflector for superimposing an electrostatic deflection field on said multi-pole lens field, and  said second deflector includes said first main deflector and said second main deflector, said second deflector deflecting the charged particle beams independently in said X and Y directions by deflecting the charged particle beams in the X directions by a first main deflection field formed by said first main deflector and a second main deflection field formed by said second main deflector and deflecting the charged particle beams in the Y directions by said second main deflection field. 9. A charged particle beam exposure system according to  claim 8 , wherein said second deflector further includes a sub deflector downstream of said N 1 -th multi-pole lens. claim 8 10. A charged particle beam exposure system according to  claim 9 , wherein said multi-pole lens is an electrostatic lens. claim 9 11. A charged particle beam exposure system according to  claim 10 , wherein said electrostatic lens is a quadrupole lens. claim 10 12. A charged particle beam exposure system according to  claim 11 , wherein said multi-pole lens has M (M=4N 2 , N 2  is a natural number of 2 or more) electrodes, adjacent N 2  electrodes thereof serving as a set of quadrupole lenses. claim 11 13. A charged particle beam exposure system comprising: a charged particle beam emitting device which generates charged particle beams with which a substrate is irradiated, said charged particle beam emitting device generating the charged particle beams at an accelerating voltage which is lower than that at which an influence of a proximity effect occurs, the proximity effect being a phenomenon in which at least one of a secondary charged particle and a reflected charged particle which is produced from the surface of the substrate irradiated with the charged particle beams influences an exposure extent of a pattern which is adjacent to a pattern to be written;  an illumination optical system which adjusts a beam diameter of the charged particle beams so that density of the charged particle beams is uniform;  a character aperture in which an aperture hole is formed in a shape corresponding to a desired pattern to be written;  a first deflector which deflects the charged particle beams by an electrostatic field so that the charged particle beams have a desired sectional shape and travel towards a desired aperture hole and which returns the charged particle beams passing through said aperture hole to an optical axis thereof;  a reducing projecting optical system which forms a multi-pole lens field so that the charged particle beams passing through said character aperture substantially reduce at the same demagnification both in X and Y directions when the optical axis extends in Z directions and form an image on the substrate without forming any crossover between said character aperture and the substrate,  wherein said reducing projecting optical system includes four multi-pole lenses, and the inside diameter of said first multi-pole lens and said second multi-pole lens is a first inside diameter and the inside diameter of said third multi-pole lens and said fourth multi-pole lens is a second inside diameter which is greater than said first inside diameter; and  a second deflector which deflects the charged particle beams passing through said character aperture by means of an electrostatic field to scan the substrate with the charged particle beams,  wherein said second deflector deflects the charged particle beams in the X directions and the charged particle beams in said Y directions independently of each other. 14. A charged particle beam exposure system according to  claim 13 , which further comprises a first shielding electrode which is provided in the vicinity of the top and bottom faces of said multi-pole lens in the Z directions. claim 13 15. A charged particle beam exposure system according to  claim 14 , wherein the inside diameter of said first shielding electrode provided between the first multi-pole lens and the second multi-pole lens, of said first shielding electrodes, is a fourth inside diameter smaller than a third inside diameter which is the inside diameter of other first shielding electrode. claim 14 16. A charged particle beam exposure system according to  claim 15 , wherein said first shielding electrode with said fourth inside diameter serves as a first alignment aperture for the charged particle beams or a first detector for the charged particle beams. claim 15 17. A charged particle beam exposure system according to  claim 16 , which further comprises second shielding electrodes which are provided in the vicinity of the top and bottom faces of said first and second deflectors, respectively. claim 16 18. A charged particle beam exposure system according to  claim 17 , wherein the inside diameter of said second shielding electrode provided in the vicinity of the top face of said first main deflector, of said second shielding electrodes, is a fifth inside diameter which is smaller than said third inside diameter. claim 17 19. A charged particle beam exposure system according to  claim 18 , wherein said second shielding electrode with said fifth inside diameter serves as a second alignment aperture for the charged particle beams or a second detector for the charged particle beams. claim 18 20. A charged particle beam exposure system according to  claim 19 , wherein each of the lens lengths of said multi-pole lenses is about 6 mm, said first inside diameter being about 5 mm, said second inside diameter being about 10 mm, and the optical length between said character aperture and the substrate being 110 mm or less. claim 19 21. A charged particle beam exposure system comprising: a charged particle beam emitting device which generates charged particle beams with which a substrate is irradiated, said charged particle beam emitting device generating the charged particle beams at an accelerating voltage which is lower than that at which an influence of a proximity effect occurs, the proximity effect being a phenomenon in which at least one of a secondary charged particle and a reflected charged particle which is produced from the surface of the substrate irradiated with the charged particle beams influences an exposure extent of a pattern which is adjacent to a pattern to be written;  an illumination optical system which adjusts a beam diameter of the charged particle beams so that density of the charged particle beams is uniform;  a character aperture in which an aperture hole is formed in a shape corresponding to a desired pattern to be written;  a first deflector which deflects the charged particle beams by an electrostatic field so that the charged particle beams have a desired sectional shape and travel towards a desired aperture hole and which returns the charged particle beams passing through said aperture hole to an optical axis thereof;  a reducing projecting optical system which forms a multi-pole lens field so that the charged particle beams passing through said character aperture form an image on the substrate without forming any crossover between said character aperture and the substrate; and  a second deflector which deflects the charged particle beams passing through said character aperture by means of an electrostatic field to scan the substrate with the charged particle beams. 22. A charged particle beam exposure system according to  claim 21 , wherein said reducing projecting optical system includes four multi-pole lenses which are controlled to form first through fourth electrostatic fields so that said first through fourth electrostatic fields sequentially form a divergent electrostatic field, a divergent electrostatic field, a convergent electrostatic field, and a divergent electrostatic field in one direction of X and Y directions and so as to sequentially form a convergent electrostatic field, a convergent electrostatic field, a divergent electrostatic field, and a convergent electrostatic field in the other direction of the X and Y directions. claim 21 23. A charged particle beam exposure system comprising: a charged particle beam emitting device which generates charged particle beams with which a substrate is irradiated, said charged particle beam emitting device generating the charged particle beams at an accelerating voltage which is lower than that at which an influence of a proximity effect occurs, the proximity effect being a phenomenon in which at least one of a secondary charged particle and a reflected charged particle which is produced from the surface of the substrate irradiated with the charged particle beams influences an exposure extent of a pattern which is adjacent to a pattern to be written;  an illumination optical system which adjusts a beam diameter of the charged particle beams so that density of the charged particle beams is uniform;  a character aperture in which an aperture hole is formed in a shape corresponding to a desired pattern to be written;  a first deflector which deflects the charged particle beams by an electrostatic field so that the charged particle beams have a desired sectional shape and travel towards a desired aperture hole and which returns the charged particle beams passing through said aperture hole to an optical axis thereof;  a reducing projecting optical system which forms a multi-pole lens field so that the charged particle beams passing through said character aperture form an image on the substrate without forming any crossover between said character aperture and the substrate; and  a second deflector which deflects the charged particle beams passing through said character aperture by means of an electrostatic field in X directions and the charged particle beams in Y directions independently of each other to scan the substrate with the charged particle beams. 24. A charged particle beam exposure system comprising: a charged particle beam emitting device which generates charged particle beams with which a substrate is irradiated, said charged particle beam emitting device generating the charged particle beams at an accelerating voltage which is lower than that at which an influence of a proximity effect occurs, the proximity effect being a phenomenon in which at least one of a secondary charged particle and a reflected charged particle which is produced from the surface of the substrate irradiated with the charged particle beams influences an exposure extent of a pattern which is adjacent to a pattern to be written;  an illumination optical system which adjusts a beam diameter of the charged particle beams so that density of the charged particle beams is uniform;  a character aperture in which an aperture hole is formed in a shape corresponding to a desired pattern to be written;  a first deflector which deflects the charged particle beams by an electrostatic field so that the charged particle beams have a desired sectional shape and travel towards a desired aperture hole and which returns the charged particle beams passing through said aperture hole to an optical axis thereof;  a reducing projecting optical system which forms a multi-pole lens field so that the charged particle beams passing through said character aperture substantially reduce at the same demagnification both in X and Y directions when the optical axis extends in Z directions and form an image on the substrate without forming any crossover between said character aperture and the substrate; and  a second deflector which includes an electrostatic deflector and deflects the charged particle beams passing through said character aperture by superimposing the electrostatic field on said multi-pole lens field to scan the substrate with the charged particle beams. 25. A charged particle beam exposure system comprising: a charged particle beam emitting device which generates charged particle beams with which a substrate is irradiated, said charged particle beam emitting device generating the charged particle beams at an accelerating voltage which is lower than that at which an influence of a proximity effect occurs, the proximity effect being a phenomenon in which at least one of a secondary charged particle and a reflected charged particle which is produced from the surface of the substrate irradiated with the charged particle beams influences an exposure extent of a pattern which is adjacent to a pattern to be written;  an illumination optical system which adjusts a beam diameter of the charged particle beams so that density of the charged particle beams is uniform;  a character aperture in which an aperture hole is formed in a shape corresponding to a desired pattern to be written;  a first deflector which deflects the charged particle beams by an electrostatic field so that the charged particle beams have a desired sectional shape and travel towards a desired aperture hole and which returns the charged particle beams passing through said aperture hole to an optical axis thereof;  a reducing projecting optical system which includes four multi-pole lenses which form a multi-pole lens field, respectively, so that the charged particle beams passing through said character aperture form an image on the substrate without forming any crossover between said character aperture and the substrate, said multi-pole lenses being controlled to form first through fourth electrostatic fields to sequentially form a divergent electrostatic field, a divergent electrostatic field, a convergent electrostatic field, and a divergent electrostatic field in X directions and to sequentially form a convergent electrostatic field, a convergent electrostatic field, a divergent electrostatic field, and a convergent electrostatic field in Y directions; and  a second deflector which includes a first main deflector and a second main deflector and which deflects the charged particle beams passing through said character aperture independently in said X and Y directions to scan the substrate with the charged particle beams by deflecting the charged particle beams in the X directions by a first main deflection field formed by said first main deflector and a second main deflection field formed by said second main deflector and deflecting the charged particle beams in the Y directions by said second main deflection field, said first main deflector being provided between said second multi-pole lens and said third multi-pole lens, and said third multi-pole lens and said fourth multi-pole lens serving as said second main deflector to superimpose an electrostatic deflection field on said multi-pole lens field.