WO2008022728A1

WO2008022728A1 - Confocal scanning microscope with optical output and pinhole assembly for the spatial filtering of a light beam

Info

Publication number: WO2008022728A1
Application number: PCT/EP2007/007156
Authority: WO
Inventors: Dieter Huhse; Jörg PACHOLIK; Karlheinz Bartzke; Michael Gölles; Ralph Lange; Dirk Döring
Original assignee: Carl Zeiss Microimaging Gmbh
Priority date: 2006-08-25
Filing date: 2007-08-14
Publication date: 2008-02-28
Also published as: DE102006040169A1

Abstract

In a confocal scanning microscope with optical output (16) the object consists in reducing the alignment outlay required for coupling the measurement light into an optical fibre (14) in the case of a positionally variable detection pinhole (12). The detection pinhole (12) is mounted in optically oriented fashion together with a beam-entrance-side first fibre end of an optical fibre (14) in a common mount (23) arranged in adjustable fashion with respect to the measurement light beam. A beam-exit-side second fibre end of the optical fibre (14) forms the optical output (16) of the scanning microscope.

Description

Confocal scanning microscope with optical output and pinhole assembly for spatial filtering of a light beam

The invention relates to a confocal scanning microscope with optical output, the at least one laser radiation source for providing an illumination beam, a scanning device for beam deflection of the illumination beam over a sample to produce a measuring light beam, a microscope unit and at least one detection channel with a detection pinhole for the measuring light beam ,

The invention further relates to a Pinholebaugruppe for spatial filtering of the measuring light in a detection channel of a confocal scanning microscope.

Laser scanning microscopes use confocal apertures (pinholes) which spatially filter the light emanating from the object to be observed before being fed to detection devices which are usually complex structures consisting of a plurality of different receivers and beam-influencing optical elements, e.g. As filters, beam splitters and the like form.

It is known from DE 197 02 753 A1 to pass the measurement light passing through the pinhole via an optical fiber to an external sensor, wherein the optical fiber can also be designed as a multimode fiber and separably connected to the scanning device of the microscope (JP 2002-221663 A ).

Associated with problems and effort are required adjustment measures to couple the emerging from the pinhole measuring light in the optical fiber. This is particularly difficult if the pinhole is changeable in its position to the measurement light beam to compensate for unavoidable fluctuations in the beam path. In addition, JP 2002-221663 A provides no measures to meet requirements for laser safety sufficient.

It is an object to reduce the necessary for the coupling of the measuring light in the optical fiber at variable position detection pinhole adjustment. According to the invention, the object is achieved in a confocal scanning microscope with optical output of the type mentioned above in that the detection pinhole is held together with a beam entry side first fiber end of an optical fiber optically aligned in a common, adjustable to measuring light beam socket and a beam outlet side second fiber end the optical fiber forms the optical output of the scanning microscope.

The fixed coupling of the optical fiber to the detection pinhole ensures that, during any movement of the detection pinhole, a consistent, optimal imaging on the end-face beam entry surface due to the entrainment of the optical fiber is ensured.

Differences in diameter between the detection pinhole and the optical fiber can be compensated particularly advantageously if an imaging optics for imaging the measurement light beam onto the beam entry surface of the optical fiber is provided between the detection pinhole and the beam-entry-side fiber end. The imaging optics can be designed both as a simple lens and as a gradient index lens.

If an uncontrolled exit of laser light through the detection pinhole and over the fiber to the outside are prevented, the optical output is to be formed as a laser-safe fiber output.

An advantageous embodiment of the invention therefore provides that the fixedly arranged or present as a loose end of the cable beam outlet fiber end is guided in a fiber bushing which has a light-sealed closure operable by a fiber connector. This can z. B. be formed by a flap with spring mechanism. Alternatively, the loose cable end of the optical fiber may be equipped with a laser-safe fiber plug. It is important that each embodiment of the invention results in a system of fiber connector and fiber connector with inherent laser safety. The existing object is further achieved by a Pinholebaugruppe for spatial filtering of a light beam in a detection channel of a confocal scanning microscope, in which a detection pinhole and a beam entrance-side first fiber end of an optical fiber to each other optically aligned are mounted in a common socket and a beam exit side second fiber end of the optical fiber optical output forms.

Advantageously, the socket has adjusting means for the common adjustment of the detection pinhole and the beam-entry-side first fiber end in relation to a measuring light beam.

The Pinholebaugruppe may have an imaging optics between the detection pinhole and the beam entrance side fiber end. In addition, a clearance for further optical elements can be provided between the detection pinhole and the optical fiber. Should z. B. the polarization properties of the measuring light are determined after passing through the detection pinhole, it is particularly advantageous if in the free space differently oriented polarizing filters can be pivoted.

Preferably find multimode fibers as optical fibers application, since in

Monomodefasern and larger Pinholedurchmessem losses may occur.

Suitable materials for the optical fibers are glass or plastic (POF, polymeric optical fibers). Other forms of optical fibers can also be used.

For maximum collection efficiency, the optical fiber's optical fiber should be greater than the largest possible optical conductivity of the detection pinhole. The optical conductivity of optics and receivers following the optical fiber in the beam path should again be greater than the optical fiber of the optical fiber. That is, the optical fiber of the optical fiber should be between the largest possible Lichtleitwert the Detektionspinholes and the smallest occurring Lichtleitwert the receiver and other optics. The invention will be explained in more detail below with reference to the schematic drawing. Show it:

Fig. 1 is a module representation of a confocal scanning microscope with optical output

2 shows a Pinholebaugruppe invention

The confocal scanning microscope shown in Fig. 1 includes a laser module 1, which preferably consists of a plurality of laser beam sources, not shown, which generate illumination light of different wavelengths. A scanning device 2, in which the illumination light is coupled as the illumination beam 3, has a main color divider 4, an xy scanner 5 and a scanning lens 6 to guide the illumination beam 3 by beam deflection over a sample 7, which is located on a microscope stage 8 Microscope unit 9 is located. A measurement light beam 10 generated thereby is directed via the main color splitter 4 and an imaging optical system 1 1 onto a confocal detection aperture (detection pinhole) 12 of a detection channel 13. _, ,

An optical fiber 14, preferably designed as a multimode fiber, into which the measuring light beam 10 emerging from the detection pinhole 12 is coupled either directly or via an additional imaging optical system 15 (FIG. 2) forms an optical output 16 with its beam-output-side second fiber end for various external receiving or measuring modules 17, 18.

The optical output 16 can be designed in different ways. According to FIG. 1, it is preferably provided that the beam-output-side second fiber end terminates in a stationary fiber bushing 19, which is connected to a laser-safe closure, such as e.g. B. a self-closing flap 20 is equipped with spring mechanism. When selectively plugging a fiber connector 22.1, 22.2 connected to a receiving or measuring module 17, 18 via an optical fiber 21.1, 21.2 into the fiber bushing 19, the flap 20 opens and when it is withdrawn it closes again. Of course, other solutions are possible to form the optical output such that no laser light unintentionally passes out. In other, not shown embodiments of the optical output, the beam output side second fiber end may also be a loose cable end, which is equipped either with a laser-safe fiber connector or with a laser-safe fiber connector.

The detection pinhole 12 and the beam entry side first fiber end of the optical fiber 14 are optically aligned with each other and as shown in FIG. 2 together in a common socket 23 supported on the z. B. adjusting means 24 to move the detection pinhole 12 and the beam entrance side first fiber end together against the measuring light beam 10 can move. Such a shift is required in order to compensate for variations in the beam path, which may arise, for example, by changes to the main color divider 4.

The preferred embodiment of the Pinholebaugruppe according to FIG. 2 provides an imaging optical system 15 for coupling the measuring light beam 10 into the optical fiber 14 between the detection pinhole 12 and the beam-entry-side fiber end. Optionally, further optical elements may be provided between the detection pinhole 12 and the optical fiber 14. For example, differently oriented polarizing filters can be pivoted in via a suitable opening in the holder 23.

Claims

claims

1 . Confocal scanning microscope with optical output, the at least one laser radiation source for providing an illumination beam, a scanning device for beam deflection of the illumination beam over a sample to produce a measuring light beam, a microscope unit and at least one detection channel with a detection pinhole for the measuring light beam, characterized in that the Detektionspinhole (12) together with a beam entrance side first fiber end of an optical fiber (14) optically aligned in a common, the measuring light beam (10) adjustably arranged socket (23) is supported and a stra h Ia exit side second fiber end of the optical fiber

(14) forms the optical output (16) of the scanning microscope.

2. Scanning microscope according to claim 1, characterized in that between the Detektionspinhole (12) and the beam entrance side fiber end an imaging optics (15) for imaging the measuring light beam (10) on the beam entry surface of the optical fiber (14) is provided.

3. Scanning microscope according to claim 2, characterized in that the imaging optics

(15) is designed as a simple lens or as gradient index lens.

4. Scanning microscope according to one of claims 1 to 3, characterized in that the optical output (16) is formed as a laser-safe fiber output closed in a light-tight manner.

5. Scanning microscope according to claim 4, characterized in that the stra h Ia exit side second fiber end of the optical fiber (14) is arranged stationary.

6. Scanning microscope according to claim 4, characterized in that the beam exit side second fiber end of the optical fiber (14) forms a loose cable end.

7. Scanning microscope according to claim 5 or 6, characterized in that the stra h ia istrittsse itige second fiber end in a fiber bushing (1 9) is guided, which has a, by a fiber connector (22.1, 22.2) operable light-tight closure.

8. scanning microscope according to claim 7, characterized in that the light-tight closure of a flap (20) is formed with spring mechanism.

9. Scanning microscope according to claim 6, characterized in that the loose cable end of the optical fiber (14) with a laser-safe fiber connector (21.1, 21.2) is equipped.

10. Pinholebaugruppe for spatial filtering of a light beam in a detection channel of a confocal scanning microscope, in which a detection pinhole (12) and a beam entrance-side first fiber end of an optical fiber (14) are mutually aligned optically aligned in a common socket (23) and the beam exit side fiber end of the optical Fiber (14) forms an optical output (16).

11. Pinholebaugruppe according to claim 10, wherein the socket (23) adjusting means (24) for the common adjustment of the detection pinhole (12) and the beam entrance side fiber end against a measuring light beam (10).

12. Pinholebaugruppe according to claim 1 1, wherein an imaging optics (15) is provided between the detection pinhole (12) and the beam entrance side fiber end.

13. Pinholebaugruppe according to claim 12, wherein the imaging optics (15) is formed as a simple lens or as a gradient index lens.

14. Pinholebaugruppe according to any one of claims 10 to 13, wherein there is a free space for further optical elements between the detection pinhole (12) and the beam entrance side fiber end.

15. Pinholebaugruppe according to claim 14, wherein in the free space differently oriented polarizing filter can be pivoted.

16. Pinholebaugruppe according to any one of claims 10 to 15, wherein the optical fiber (14) is provided a multi-mode fiber.