Patent Number: 
Section: claims

1. A lithography tool for patterning resist coated substrates comprising:a charged particle source, configured to produce a charged particle beam;a first lens positioned below said charged particle source, said first lens being configured to form said charged particle beam into a substantially laminar charged particle beam;a stage positioned below said first lens, for carrying said resist coated substrates;a second lens positioned between said first lens and said stage, said second lens being configured to focus said substantially laminar charged particle beam onto the surface of said resist coated substrate; andan alignment deflector/stigmator positioned between said first lens and said second lens, said alignment deflector/stigmator comprising eight electrodes in an octupole configuration. 2. A lithography tool as in claim 1, wherein said eight electrodes are electrically connected to an alignment deflector control configured to supply voltages to each of said eight electrodes in said alignment deflector/stigmator to simultaneously generate a rotatable quadrupole electric field transverse to said charged particle beam for stigmating said charged particle beam and a rotatable dipole electric field transverse to said charged particle beam for deflecting said charged particle beam. 3. A lithography tool as in claim 1, further comprising a beam blanker positioned between said alignment deflector/stigmator and said second lens, for blanking said substantially laminar charged particle beam. 4. A lithography tool for patterning resist coated substrates comprising:a charged particle source, configured to produce a charged particle beam;a first lens positioned below said charged particle source, said first lens being configured to form said charged particle beam into a substantially laminar charged particle beam;a stage positioned below said first lens, for carrying said resist coated substrates;a second lens positioned between said first lens and said stage, said second lens being configured to focus said substantially laminar charged particle beam onto the surface of said resist coated substrate;an alignment deflector/stigmator positioned between said first lens and said second lens, said alignment deflector/stigmator comprising eight electrodes in an octupole configuration;a patterned beam-defining aperture positioned between said alignment deflector/stigmator and said second lens, said patterned beam-defining aperture being configured to block a large portion of charged particles in said substantially laminar charged particle beam that cannot be focused by said second lens into a predetermined beam profile at the surface of said resist coated substrate; andwherein said electron source, first lens, alignment deflector/stigmator, patterned beam-defining aperture, and second lens are configured (1) to form a non-circular shaped beam at the surface of said resist coated substrate and (2) to map charged particle current passing through multiple separated areas of said beam-defining aperture onto a single area at said resist coated substrate. 5. A lithography tool as in claim 4, wherein said eight electrodes are electrically connected to an alignment deflector control configured to supply voltages to each of said eight electrodes in said alignment deflector/stigmator to generate a rotatable dipole electric field transverse to said charged particle beam for deflecting said charged particle beam. 6. A lithography tool as in claim 4, wherein said eight electrodes are electrically connected to an alignment deflector control configured to supply voltages to each of said eight electrodes in said alignment deflector/stigmator to generate a rotatable quadrupole electric field transverse to said charged particle beam for stigmating said charged particle beam. 7. A lithography tool as in claim 4, wherein said eight electrodes are electrically connected to an alignment deflector control configured to supply voltages to each of said eight electrodes in said alignment deflector/stigmator to simultaneously generate a rotatable quadrupole electric field transverse to said charged particle beam for stigmating said charged particle beam and a rotatable dipole electric field transverse to said charged particle beam for deflecting said charged particle beam. 8. A lithography tool as in claim 4, further comprising a beam blanker positioned between said alignment deflector/stigmator and said patterned beam-defining aperture, for blanking said substantially laminar charged particle beam. 9. A lithography tool for patterning resist coated substrates comprising:a charged particle source, configured to produce a charged particle beam;a first lens positioned below said charged particle source, said first lens being configured to form said charged particle beam into a substantially laminar charged particle beam;a stage positioned below said first lens, for carrying said resist coated substrates;a second lens positioned between said first lens and said stage, said second lens being configured to focus said substantially laminar charged particle beam onto the surface of said resist coated substrate; anda beam deflector positioned between said first lens and said second lens, wherein said beam deflector is a double deflector, configured to allow telecentric scanning of said beam;wherein said second lens is configured to allow the effective axis of said second lens to move paraxially with said beam during said telecentric scanning. 10. A high throughput charged particle direct write lithography system comprising:a charged particle optical assembly configured to (1) produce a multiplicity, N, of high current density charged particle non-circular shaped-beams focused on a specimen plane and (2) vector scan said charged particle shaped-beams across said specimen plane;wherein each of said multiplicity of high current density charged particle shaped-beams has a current density, Ia, and an area A which satisfy the equations:Ia≧2000 Amperes per square centimeter;100≧N≧36;A=p2; and120>p>30 nanometers. 11. A charged particle direct write lithography system as in claim 10, wherein said charged particle optical assembly comprises a multiplicity of electron beam columns each with a patterned beam defining aperture.