Patent Number: 
Section: claims

1. A charged particle shaped beam column, comprising:a charged particle source;a gun lens configured to provide a charged particle shaped beam approximately parallel to the optic axis of said column;an objective lens configured to form said charged particle shaped beam on the surface of a substrate, wherein the disk of least confusion of said objective lens does not coincide with the surface of said substrate;a first optical element with 8N poles disposed radially symmetrically about the optic axis of said column, said first optical element being positioned between said gun lens and said objective lens, wherein N is an integer greater than or equal to 1 and wherein the 8N poles create a specific desired non-circular beam shape by selectively enlarging aberrations present in said charged particle shaped beam; anda first power supply configured to apply excitations to said 8N poles of said first optical element to provide an octupole electromagnetic field. 2. A charged particle shaped beam column as in claim 1, wherein N equals 2 and said octupole electromagnetic field is rotatable about the optic axis. 3. A charged particle shaped beam column as in claim 1, wherein said charged particle shaped beam is a square beam. 4. A charged particle shaped beam column as in claim 1, wherein said octupole electromagnetic field is an electrostatic field and said excitations are voltages. 5. A charged particle shaped beam column as in claim 1, wherein said octupole electromagnetic field is a magnetic field and said excitations are currents. 6. A charged particle shaped beam column as in claim 1, further comprising:a second optical element with 8P poles disposed radially symmetrically about the optic axis of said column, said second optical element being positioned between said gun lens and said first optical element, wherein P is an integer greater than or equal to 1;a second power supply configured to apply excitations to said 8P poles of said second optical element to provide a first quadrupole electromagnetic field;a third optical element with 8Q poles disposed radially symmetrically about the optic axis of said column, said third optical element being positioned between said second optical element and said first optical element, wherein Q is an integer greater than or equal to 1;a third power supply configured to apply excitations to said 8Q poles of said third optical element to provide a first combined quadrupole and octupole electromagnetic field;a fourth optical element with 8R poles disposed radially symmetrically about the optic axis of said column, said fourth optical element being positioned between said third optical element and said first optical element, wherein R is an integer greater than or equal to 1; anda fourth power supply configured to apply excitations to said 8R poles of said fourth optical element to provide a second combined quadrupole and octupole electromagnetic field;wherein said first power supply is further configured to apply excitations to said 8N poles of said first optical element to provide both an octupole electromagnetic field and a second quadrupole electromagnetic field. 7. A charged particle shaped beam column as in claim 6, wherein:in a first plane containing the optic axis:said second and fourth optical elements and said second and fourth power supplies are configured to create a defocusing field; andsaid first and third optical elements and said first and third power supplies are configured to create a focusing field; andin a second plane containing the optic axis and perpendicular to said first plane:said second and fourth optical elements and said second and fourth power supplies are configured to create a focusing field; andsaid first and third optical elements and said first and third power supplies are configured to create a defocusing field. 8. A charged particle shaped beam column as in claim 6, wherein said octupole electromagnetic field, said first and second quadrupole electromagnetic fields, and said first and second combined quadrupole and octupole electromagnetic fields are electrostatic fields and said excitations are voltages. 9. A charged particle shaped beam column as in claim 6, wherein said octupole electromagnetic field, said first and second quadrupole electromagnetic fields, and said first and second combined quadrupole and octupole electromagnetic fields are magnetic fields and said excitations are currents. 10. A charged particle shaped beam column as in claim 1, further comprising a beam defining aperture centered on the optic axis and positioned between said charged particle source and said first optical element. 11. A method of forming a charged particle shaped beam in a charged particle optical column, comprising the steps of:forming a charged particle beam approximately parallel to the optic axis of said charged particle column;creating an octupole electromagnetic field to induce azimuthally dependent deflection of said charged particle beam, wherein the azimuthal angle is about the optic axis of said charged particle column, in a plane perpendicular to the optic axis; andforming a non-circular charged particle shaped beam on a substrate by controlling the deflections of said charged particle beam to enlarge aberrations present in said charged particle beam. 12. A method as in claim 11, wherein said octupole electromagnetic field is created by:a first optical element with 8N poles disposed radially symmetrically about the optic axis of said column, wherein N is an integer greater than or equal to 1; anda first power supply configured to apply excitations to said poles of said first optical element. 13. A method as in claim 12, wherein N equals 2. 14. A method as in claim 12, further comprising the steps of:creating a first combined octupole and quadrupole electromagnetic field to induce azimuthally dependent deflection of said charged particle beam;creating a second combined octupole and quadrupole electromagnetic field to induce further azimuthally dependent deflection of said charged particle beam; andcreating a third combined octupole and quadrupole electromagnetic field to induce yet further azimuthally dependent deflection of said charged particle beam;wherein, said step of creating an octupole electromagnetic field further includes creating a quadrupole electromagnetic field. 15. A method as in claim 11, wherein said forming a charged particle shaped beam step is implemented by an objective lens, the disk of least confusion of said objective lens not coinciding with the surface of said substrate. 16. A method as in claim 1, wherein the charged particle is an electron. 17. A high throughput charged particle direct write lithography system comprising:a charged particle optical assembly configured to (1) produce a plurality M of high current density charged particle non-circular shaped-beams focused on the surface of a substrate and (2) vector scan said charged particle shaped-beams across the surface of said substrate;wherein each of said plurality of high current density charged particle shaped-beams has a current density, Ia, and an area A which satisfy the equations:Ia ≧1000 Amperes per square centimeter;300≧M ≧10;A=p2; and120>p>10 nanometers;wherein said charged particle optical assembly includes N charged particle columns, each of said charged particle columns forming a charged particle beam, each of said charged particle columns including at least one optical element with 8N poles disposed radially symmetrically about the optic axis of said column, N being an integer greater than or equal to 1, each of said optical elements being configured to produce azimuthally dependent deflection of said corresponding charged particle beam, the azimuthal angle being about the optic axis of said corresponding charged particle column, in a plane perpendicular to the optic axis; andwherein the 8N poles are used to shape the non-circular shaped beams by selectively enlarging aberrations present in said charged particle non-circular shaped-beams. 18. A charged particle direct write lithography system as in claim 17, wherein each of said columns further comprises:a charged particle source;a gun lens configured to provide a charged particle beam approximately parallel to the optic axis of said column;an objective lens configured to form a high current density charged particle non-circular shaped-beam on the surface of a substrate, wherein the disk of least confusion of said objective lens does not coincide with the surface of said substrate; anda first power supply configured to apply excitations to said 8N poles of said first optical element to provide an octupole electromagnetic field;wherein said first optical element is positioned between said condenser lens and said objective lens. 19. A high throughput charged particle direct write lithography system comprising:a charged particle optical assembly configured to (1) produce a plurality, M, of high current density charged particle non-circular shaped-beams focused on the surface of a substrate and (2) vector scan said charged particle shaped-beams across the surface of said substrate;wherein each of said plurality of high current density charged particle shaped-beams has a current density, Ia, and an area A which satisfy the equations:Ia ≧5000 Amperes per square centimeter;100≧M≧10;A =p2; and120>p>20 nanometers;wherein said charged particle optical assembly includes N charged particle columns, each of said charged particle columns forming a charged particle beam, each of said charged particle columns including at least one optical element with 8N poles disposed radially symmetrically about the optic axis of said column, N being an integer greater than or equal to 1, each said optical element being configured to produce azimuthally dependent deflection of said corresponding charged particle beam, the azimuthal angle being about the optic axis of said corresponding charged particle column, in a plane perpendicular to the optic axis; andwherein the 8N poles are used to shape the non-circular shaped beams by selectively enlarging aberrations present in said charged particle non-circular shaped-beams.