WO2004090603A1 - Plan apochromatic microscope objective - Google Patents

Abstract

The invention relates to a plan apochromatic microscope objective. One such microscope objective comprises four lens groups with a total of ten lenses. Viewed from the object plane, the first group consists of two lenses having centres of curvature in the direction of the object plane and a total focal distance of between 5 mm and 10 mm, the refractive powers of the lenses differing from each other by a maximum of 30 %. The second group consists of two lenses which are sealed together and - viewed from the object plane - follow the refractive power sequence negative-positive with a minimum total focal distance of 20 mm. The third group consists of four lenses which are sealed together and follow the refractive power sequence positive-negative-positive-negative with a minimum total focal distance of 30 mm, the lengths of the individual focal distances being less than 30 mm. The fourth group consists of two lenses, the lens facing the object plane having a positive focal distance and the other having a negative focal distance, and the Abbe value of the lens facing the object plane is less than 40. The total focal distance of this group is between -25 mm and -10 mm.

Description

 Plan-apochromatic microscope objective

The large number of applications in microscopy has led to microscope objectives having to meet an ever increasing number of different requirements. Recently, the investigation of biological objects with fluorescence has become increasingly important. Lenses with a high numerical aperture with regard to improved resolution and brightness are advantageous for examining such objects. A large aperture, however, is faced with the difficulty of producing a level and well-corrected image as possible.

In order to nevertheless achieve both, various complex solutions are proposed in the prior art. In the published patent application JP 091 01 462 A, a system with fifteen lenses is described, which has a numerical aperture of 0.95, which is the highest possible value for air, at a magnification of approximately 100 times.

A similarly complex system is described in US 2002/0024744 AI. Fifteen or more lenses are also used here. Apertures larger than 1 can be achieved with the microscope objective described, since immersion liquids are used.

The object of the invention is therefore to develop a plan-apochromatic microscope objective with a numerical aperture in air that is as high as possible, which at the same time requires as few lenses as possible, in order to save manufacturing costs. This object is achieved by a plan-apochromatic microscope objective, which comprises a first, second, third and fourth lens group in order from the object plane. The first lens group with a positive total focal length consists of a first and a second lens, the total focal length of the two lenses being greater than 5 mm and less than 10 mm, the refractive powers of the two lenses differing by a maximum of 30%, and the radii of curvature centers of the two lenses are located on the property side. The second lens group with a total focal length of more than 20 mm consists of a third lens with negative refractive power and a fourth lens with positive refractive power, the third and fourth lenses being cemented together. The third lens group with a total focal length with an amount of more than 30 mm consists of a fifth, sixth, seventh and eighth lens which are cemented to one another and whose individual focal lengths are less than 30 mm in magnitude, the fifth and the seventh Lens has a positive focal length, and the sixth and eighth lenses have a negative focal length. Finally, the fourth lens group with a total focal length between -25 mm and -10 mm consists of a ninth lens with a positive focal length and a material whose Abbe number is less than 40, and a tenth lens with a negative focal length. An advantageous embodiment of the microscope objective results from the design data for a objective with the magnification lOOx specified in the subclaim. The tolerances for the radii - specified in Newton rings - are less than 4 and the deviations in lens thicknesses and distances are less than 0.06 mm. The maximum deviations in the refractive indices should not exceed 5-10 ⁴ , and the relative deviations in the number of refractions should be less than 0.5%. Compared to the microscope objectives known from the prior art with approximately the same performance data, the objective according to the invention has a small number of lenses, in total only ten lenses are required. The numerical aperture reaches the highest possible value in air of 0.95, the image field remains flat and is vignetting-free towards the edge. The colors are apochromatically corrected in the visual range from approx. 430 nm to approx. 700 nm. The image quality is only limited by diffraction over the entire image field area of 25 mm in diameter and an image scale of 100x. In addition, the refractive power distribution in the lens enables the lens exit pupil to be displaced into the rear area, which creates better conditions for contrasting methods. Finally, the lens has a high level of light transmission in the near ultraviolet range.

The microscope objective will be explained in the following using an exemplary embodiment. In the accompanying drawings

Fig.l a possible lens construction and Fig.2 transverse aberrations at different wavelengths in the center of the image, in the image zone, and at the edge of the image of a lens designed according to the design data of the subclaim.

Fig.l shows a sectional view of the lens according to the invention. The object plane is on the far left and not shown, the closest is a first lens group Gl. This comprises a first lens L1 and a second lens L2. The radii of curvature centers of both lenses Ll and L2 are located on the object side, the total focal length of the first lens group Gl is positive, the total focal length of this group being between 5 mm and 10 mm and the individual powers of the two lenses Ll and L2 differing by no more than 30% , This is followed by a second lens group G2 with a positive total focal length of more than 20 mm from two lenses L3 and L4 cemented together at a distance of approximately 0.1 mm. The third lens L3 has a negative refractive power, the fourth lens L4 has a positive refractive power. Then follows a third lens group G3 consisting of a total of four lenses L5, L6, L7 and L8 cemented together. All lenses are cemented together and the refractive power sequence in the third lens group G3 is positive-negative-positive-negative. The amounts of the individual refractive powers of the lenses L5, L6, L7 and L8 are less than 30 mm, but the amount of the total focal length of the third lens group G3 is greater than 30 mm. This is followed by a fourth lens group G4. This consists of two lenses L9 and L10 arranged at a clear distance from one another, the ninth lens L9 having a positive refractive power and the tenth lens L10 having a negative refractive index. The material of the ninth lens L9 has an Abbe number that is less than 40. The total focal length of the fourth lens group G4 is negative and is in the range between -25 mm and -10 mm. The emerging light can now be imaged on a tube.

The possible design of a tube system adapted to the design data of the subclaim is given in the following table: n _e

Lens 00

121.500

167.8740

T-Ll 7,000 1.58212 53.60

^■ 220.6400

100.00 oo T-L2 30,000 1.51872 63.96 oo

42.5327

image plane

The refractive indices relate to a wavelength of 546.07 nm. The reduction numbers v _e were, as in the subclaim, from the equation

= - n _β - n _F , --- n _c , calculated. Here n _{e is} the refractive index at a wavelength of 546.07 nm, n _c - the refractive index at a wavelength of 643.85 nm and n _F. the refractive index at a wavelength of 479.99 nm.

2 shows an image defect of a lens, which is based on the design data of the subclaim, namely the transverse aberration, ie the color deposits of the opening rays of a light beam from the associated main ray, at three points in the image field with a radius of y'm = 12.5 mm , namely in the center of the image on the axis at y '= 0.0mm (a), in the image zone at a point y' = -8.99 mm (b) and at the edge of the image at y '= -12.5 mm (c ) for three different wavelengths. The aberrations in a world length of 546.07 nm ("green") with a solid line, the aberrations at a wavelength of 643.85 nm ("red") with a dashed line and the aberrations at a wavelength of 479.99 nm ( "Blue") is shown with a dotted line. For the points outside the center of the image, the transverse aberrations for the color "green" at 546.07 nm are given in the meridional course with a solid line and in the sagittal course with a dash-dot line. In addition, the gutter error in the sagittal section is indicated on one side as a dash-dot-dot line along the opening coordinate. The channel defect is caused by sagittal coma, which causes the sagittal rays in the image space to span a channel-shaped curved surface. A graduation on the y-axis corresponds to 0.1 mm. As you can see, the lens has very well corrected values for all wavelengths, which are below the visibility limit over the entire image field. The lens can therefore rightly be called plan-apochromatic.

LIST OF REFERENCE NUMBERS

Gl, ..., G4 lens groups

Ll, ..., L10 lenses

Claims

claims

1. Plan-apochromatic microscope objective, comprising ordered from the object plane - a first lens group (Gl) with a positive total focal length (fi) between 5 mm and 10 mm from a first and a second lens (L1) or (L2), whereby • the refractive powers of the two lenses (Ll) and (L2) deviate from each other by a maximum of 30%, and • the radii of curvature of the two lenses (Ll) and (L2) are on the object side, a second lens group (G2) with a total focal length (f ₂ ) of more than 20 mm from a third lens (L3) with negative refractive power (L3) and a fourth lens (L4) with positive refractive power, the third and fourth lenses (L3) and (L4) being cemented together, a third Lens group (G3) with a total focal length (f ₃ ) with an amount of more than 30 mm from a fifth, sixth, seventh and eighth lens (L5), (L6), (L7) and (L8) which are cemented together and their individual focal lengths are less than 30 mm si nd, wherein the fifth lens (L5) and the seventh lens (L7) have a positive focal length, and the sixth lens (L6) and the eighth lens (L8) have a negative focal length, and a fourth lens group (G4) with a total focal length (f ₄ ) between -25 mm and -10 mm from a ninth lens (L9) with a positive focal length made of a material whose Abbe number is less than 40, and a tenth lens (L10) with a negative focal length. Plan-apochromatic microscope objective according to claim 1, characterized by the following design data with radii r, thicknesses d and distances a in mm, refractive indices n _e at a wavelength of 546.07 nm and numbers

rdan _e v _e

Object level oo

0,700

-1.5400

Ll 2,200 1,88577 40.76

-2.3030

0.082

-33.7410

L2 4,700 1.48794 84.07

-5.7450

0,102

-47.3150

L3 0.900 1.61664 44.27

8.0590

L4 5,840 1.48794 84.07

-8.2920

0,180

29.4298

L5 5.900 1.62247 63.18

-6.0424

L6 1,000 1.61664 44.27

6.9790

L7 5,200 1.48794 84.07

-6.1313

L8 1.040 1.71616 53.61

-14.7470

4,343

26.8005

L9 11.300 1.72310 29.29

-13.1430

3,363

-6.501

L10 1.05 1.80832 46.24

8,004

0,600

Tube oo