Immersion objective for microscopes and use thereof

The invention claimed is: 1. A microscope immersion objective having a numerical aperture of NA>1.36, the microscope immersion objective comprising: a front lens group disposed at an object end of the microscope immersion objective, the front lens group including: a first optical element, the first optical element being a plane parallel plate comprising two parallel planar sides, and a second optical element being disposed, relative to the first optical element, distal to the object of the microscope immersion objective, the second optical element comprising: a hyper-hemisphere portion, and a planar side portion, wherein at least one of the two parallel planar sides of the plane parallel plate and the planar side portion of the second optical element each have a smooth planar surface, and wherein the smooth planar surface of the at least one of the two parallel planar sides of the plane parallel plate is wrung together with the smooth planar surface of the planar side portion of the second optical element. 2. The microscope immersion objective of claim 1 , wherein the plane parallel plate projects beyond the planar side of the hyper-hemisphere. 3. The microscope immersion objective of claim 2 , wherein the plane parallel plate enables mechanical retention of the front lens group. 4. The microscope immersion objective of claim 1 , wherein a magnification of the microscope immersion objective is greater than 50x and less than 200x. 5. The microscope immersion objective of claim 1 , wherein the numerical aperture is NA>1.40. 6. The microscope immersion objective of claim 1 , wherein a thickness of the plane parallel plate is not greater than 1 mm. 7. The microscope immersion objective of claim 1 , wherein the microscope immersion objective is a plan apochromatic objective. 8. The microscope immersion objective of claim 1 , further comprising: a second lens group including a unipotential lens and a cemented lens having three cemented surfaces, and a third lens group including a remainder of the objective; wherein a focal length f (G 1 ) of the front lens group and a focal length f (objective) of the microscope immersion objective satisfy the condition: 3.0<f (G 1 )/f (objective)<4.0, wherein a focal length f (G 2 ) of the second lens group and the focal length f (objective) of the microscope immersion objective satisfy the condition: 6.0<f (G 2 )/f (objective) <7.0, and wherein a focal length f (G 3 ) of the third lens group and the focal length f (objective) of the microscope immersion objective satisfy the condition: −15.5<f (G 3 )/f (objective)<-14.5. 9. A microscopy method comprising: providing a microscope immersion objective having a numerical aperture of NA>1.36, the microscope immersion objective comprising a front lens group disposed at an object end of the microscope immersion objective, the front lens group including: a first optical element, the first optical element being a plane parallel plate comprising two parallel planar sides, and a second optical element being disposed, relative to the first optical element, distal to the object of the microscope immersion objective, the second optical element comprising: a hyper-hemisphere portion, and a planar side portion, wherein at least one of the two parallel planar sides of the plane parallel plate and the planar side portion of the second optical element each have a smooth planar surface, and wherein the smooth planar surface of the at least one of the two parallel planar sides of the plane parallel plate is wrung together with the smooth planar surface of the planar side portion of the second optical element; and using the microscope immersion objective for TIRF microscopy or localizing microscopy. 10. The microscope immersion objective of claim 1 , wherein the smooth planar surface of the at least one of the two parallel planar sides of the plane parallel plate and the smooth planar surface of the planar side portion of the second optical element are rigidly interconnected as the sole result of molecular forces of attraction. 11. The microscope immersion objective of claim 1 , wherein the smooth planar surface of the at least one of the two parallel planar sides of the plane parallel plate and the smooth planar surface of the planar side portion of the second optical element are wrung together without any microstructuring. 12. The microscopy method of claim 9 , wherein the smooth planar surface of the at least one of the two parallel planar sides of the plane parallel plate and the smooth planar surface of the planar side portion of the second optical element are rigidly interconnected as the sole result of molecular forces of attraction. 13. The microscopy method of claim 9 , wherein the smooth planar surface of the at least one of the two parallel planar sides of the plane parallel plate and the smooth planar surface of the planar side portion of the second optical element are wrung together without any microstructuring.