Patent Number: 
Section: claims

1. A particle-optical appliance provided with an objective lens and with aberration-correcting means for correcting lens errors of the objective lens, which aberration-correcting means comprise:a first group of optical elements, consecutively consisting of a first, a second and a third quadrupole lens and a first octupole;a second group of optical elements, consecutively consisting of a second octupole and a fourth, a fifth and a sixth quadrupole lens; andat least one third octupole, placed outside both groups of optical elements,whereby the first and the second octupole and the third and the fourth quadrupole lens are placed between the first and the second quadrupole on the one hand and the fifth and the sixth quadrupole on the other hand,in which the quadrupole lenses determine the paths of electrically charged particles in the aberration-correcting means in such a manner as to cause imaging of octupoles upon one another,characterized in thatin a first axial plane, the first and the second octupole are not imaged upon one another, and the second and the third octupole are imaged upon one another;in a second axial plane perpendicular to the first axial plane, the first and the second octupole are not imaged upon one another, and the first and the third octupole are imaged upon one another; andan axial beam in the first axial plane passes through the axial point of the first octupole and in the second axial plane passes through the axial point of the second octupole,as a result of which third-order lens errors are corrected, and fifth-order lens errors are, at the least, minimized. 2. A particle-optical apparatus according to claim 1, wherein the quadrupole field of the third quadrupole lens and the octupole field of the first octupole overlap one another at least partially, and the quadrupole field of the fourth quadrupole lens and the octupole field of the second octupole overlap one another at least partially. 3. A particle-optical apparatus according to claim 1, wherein the third octupole is located at that side of the aberration-correcting means at which the objective lens that is to be corrected in the particle-optical appliance is not located. 4. A particle-optical apparatus according to claim 1, wherein the third octupole is divided into a first portion and an equal second portion by a cross-section perpendicular to the optical axis, which portions are respectively located on opposite sides of both groups of optical elements, andwherein a plane of mirror symmetry perpendicular to the optical axis is present in such a manner that, when mirrored with respect to said symmetry plane, the positions of the three quadrupoles and the octupole of the first group, and the first portion of the third octupole, yield the locations of the three quadrupoles and the octupole of the second group, and of the second portion of the third octupole, whereby the excitations of the quadrupoles of the first group are opposite to those of the corresponding quadnipoles of the second group. 5. A particle-optical apparatus according to claim 1, wherein the third and the forth quadrupole lens are each embodied as a combination of magnetostatic and electrostatic quadrupoles. 6. A particle-optical apparatus according to claim 5, wherein a further quadrupole lens from the first group of optical elements and a further quadrupole lens from the second group of optical elements are each embodied as a combination of a magnetostatic and an electrostatic quadrupole. 7. A particle-optical apparatus according to claim 5, wherein a transfer lens system is placed between the aberration-correcting means and the objective to be corrected, which system causes the axial particle rays to pass through a point of intersection in the optical axis, at the location of which point of intersection a seventh quadrupole is placed. 8. A particle-optical apparatus according to claim 6, wherein the three quadrupole lenses from the first group of optical elements and the three quadrupole lenses from the second group of optical elements are all embodied as a combination of magnetostatic and electrostatic quadrupoles, and wherein the first, the second, the fifth and the sixth quadrupole are also embodied to be achromatic. 9. A particle-optical apparatus according to claim 1, wherein at least three further octupoles are added, which are placed at the locations of the first, the second and the third octupole, respectively, which first, second and third octupoles are even octupoles and which first, second and third further octupoles are uneven octupoles, each of which uneven octupoles, as a result of a cross-section perpendicular to the optical axis, consists of a first and a second portion, in which the ratio of the excitations of the first and the second portion of each uneven octupole is such that the contribution of the uneven octupoles to the third-order axial aberrations is equal to zero, and in which the total excitation of all uneven octupoles is such that the anisotropic coma of the combination of the aberration-correcting means and the objective lens to be corrected is equal to zero. 10. A particle-optical apparatus according to claim 2, wherein the third octupole is located at that side of the aberration-correcting means at which the objective lens that is to be corrected in the particle-optical appliance is not located. 11. A particle-optical apparatus according to claim 2:wherein the third octupole is divided into a first portion and an equal second portion by a cross-section perpendicular to the optical axis, which portions are respectively located on opposite sides of both groups of optical elements; anda plane of mirror symmetry perpendicular to the optical axis is present in such a manner that, when mirrored with respect to said symmetry plane, the positions of the three quadrupoles and the octupole of the first group, and the first portion of the third octupole, yield the locations of the three quadrupoles and the octupole of the second group, and of the second portion of the third octupole, whereby the excitations of the quadrupoles of the first group are opposite to those of the corresponding quadrupoles of the second group. 12. A particle-optical apparatus according to claim 2, wherein the third and the forth quadrupole lens are each embodied as a combination of magnetostatic and electrostatic quadrupoles. 13. A particle-optical apparatus according to claim 3, wherein the third and the forth quadrupole lens are each embodied as a combination of magnetostatic and electrostatic quadrupoles. 14. A particle-optical apparatus according to claim 4, wherein the third and the forth quadrupole lens are each embodied as a combination of magnetostatic and electrostatic quadrupoles. 15. A particle-optical apparatus according to claim 10, wherein the third and the forth quadrupole lens are each embodied as a combination of magnetostatic and electrostatic quadrupoles. 16. A particle-optical apparatus according to claim 11, wherein the third and the forth quadrupole lens are each embodied as a combination of magnetostatic and electrostatic quadrupoles. 17. A particle-optical apparatus according to claim 12, wherein a further quadrupole lens from the first group of optical elements and a further quadrupole lens from the second group of optical elements are each embodied as a combination of a magnetostatic and an electrostatic quadrupole. 18. A particle-optical apparatus according to claim 13, wherein a further quadrupole lens from the first group of optical elements and a further quadrupole lens from the second group of optical elements are each embodied as a combination of a magneto static and an electrostatic quadrupole. 19. A particle-optical apparatus according to claim 14, wherein a further quadrupole lens from the first group of optical elements and a further quadrupole lens from the second group of optical elements are each embodied as a combination of a magnetostatic and an electrostatic quadrupole. 20. A particle-optical apparatus according to claim 12, wherein a transfer lens system is placed between the aberration-correcting means and the objective to be corrected, which system causes the axial particle rays to pass through a point of intersection in the optical axis, at the location of which point of intersection a seventh quadrupole is placed. 21. A particle-optical apparatus according to claim 13, wherein a transfer lens system is placed between the aberration-correcting means and the objective to be corrected, which system causes the axial particle rays to pass through a point of intersection in the optical axis, at the location of which point of intersection a seventh quadrupole is placed. 22. A particle-optical apparatus according to claim 14, wherein a transfer lens system is placed between the aberration-correcting means and the objective to be corrected, which system causes the axial particle rays to pass through a point of intersection in the optical axis, at the location of which point of intersection a seventh quadrupole is placed. 23. A particle-optical apparatus according to claim 17, wherein the three quadrupole lenses from the first group of optical elements and the three quadrupole lenses from the second group of optical elements are all embodied as a combination of magnetostatic and electrostatic quadrupoles, and wherein the first, the second, the fifth and the sixth quadrupole are also embodied to be achromatic. 24. A particle-optical apparatus according to claim 18, wherein the three quadrupole lenses from the first group of optical elements and the three quadrupole lenses from the second group of optical elements are all embodied as a combination of magnetostatic and electrostatic quadrupoles, and wherein the first, the second, the fifth and the sixth quadrupole are also embodied to be achromatic. 25. A particle-optical apparatus according to claim 19, wherein the three quadrupole lenses from the first group of optical elements and the three quadrupole lenses from the second group of optical elements are all embodied as a combination of magnetostatic and electrostatic quadrupoles, and wherein the first, the second, the fifth and the sixth quadrupole are also embodied to be achromatic.