KR20150116999A - Micro Raman and photo-luminescence spectral analysis apparatus for multi-channel excitation laser source switching - Google Patents

Abstract

The present invention relates to a micro-Raman and fluorescence spectrometer for switching a multi-channel excitation light source, and more particularly to a micro-Raman and fluorescence spectrometer for switching a multi-channel excitation light source, A first pinhole through which the excitation light source reflected by the first parabolic mirror passes, a beam splitter through which the excitation light source passing through the first pinhole is deflected, A second parabolic mirror for reflecting the excitation light source refracted by the beam splitter, a second reflector for reflecting the excitation light source reflected by the second parabolic mirror, and an excitation light source reflected by the second reflector, And Raman scattered light or fluorescence collected through the objective lens is reflected by the second parabolic mirror and is output through the beam splitter, A third parabolic mirror through which the scattered light having passed through the second pinhole and spatially noise-free is reflected, and a third parabolic mirror which is reflected by the third parabolic mirror in the form of parallel light, And a third reflector selectively reflecting the Raman scattered light or fluorescence passing through the filter, and a fourth reflector selectively reflecting the fluorescence by the third reflector, wherein the Raman scattered light or the fluorescence is selectively reflected by the third reflector. And a fifth parabolic mirror, and more particularly, to a micro-Raman and fluorescence spectrometer for multi-channel excitation light source switching.
According to the present invention, excitation light sources of a wavelength ranging from a wide area can be used by intersecting excitation light sources by removing the chromatic aberration by focusing the Raman scattering light or the fluorescence signals and by forming the spherical mirrors to make parallel light There is an effect.
In order to obtain a spectrum with a corrected wavelength in real time, a lamp light source having a reference line spectrum and a Raman optical signal or a fluorescence signal obtained from the Raman spectroscopic analysis chamber are spatially separated and incident on the spectrometer, The spectrum of Raman scattering light or fluorescence in which the wavelength axis of the two-dimensional detector is corrected can be obtained based on the line spectra.

Description

[0002] Micro-Raman and photo-luminescence spectral analysis apparatus for multi-channel excitation laser source switching [

The present invention relates to a spectroscopy chamber for obtaining a Raman optical signal or a photo-luminescence signal consisting of mirrors for micro-Raman spectroscopy, Spherical mirrors are used to focus the excitation light sources and the output optical signals to obtain optical signals or fluorescence signals or to generate color aberration when making collimating light. Channel excitation light source capable of minimizing deterioration in performance of an output optical signal by alternately using a plurality of light sources alternately in a wide region, that is, a wavelength region from an ultraviolet wavelength to an infrared wavelength, Switching micro-Raman and a fluorescence spectrometer.

In general, a Raman optical signal is an optical signal that is scattered when an excitation light source is irradiated on a sample, and a part of the light source is deviated from the traveling direction of the irradiated light and propagates in the other direction.

Therefore, these Raman optical signals emit a signal in the vicinity of the excitation light source in the wavelength direction. The optical signals are very weak compared to the fluorescence signal.

So, if a sample has a fluorescent signal and uses a nearby excitation source where the fluorescence signal can appear, it is usually not easy to get a Raman optical signal buried in a fluorescent signal.

In this case, the excitation light source is used to avoid the fluorescent signal region. Therefore, in the Raman spectroscopic apparatus, a plurality of excitation light sources are attached in a wavelength manner so as to be selected according to the sample, and are used by switching.

On the other hand, many micro-Raman spectroscopy devices now remove out of focal light outside the focal plane of the sample to improve the signal to noise ratio of the Raman optical signal The principle uses the principle of confocal microscopy.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is an illustration showing a conventional micro-Raman spectroscopic apparatus. Referring to FIG. 1, a micro-Raman spectroscopy apparatus using the principle of conventional confocal microscopy uses a lens system.

Particularly, a lens is used to focus the excitation light source to a pinhole aperture, and a collimating lens is used to introduce the light emitted from the pinhole into the objective lens in parallel light. use.

On the other hand, the Raman light having passed through the objective lens inversely passes through the other pinhole due to the balanced lens, and scattered light including light reflected from the local portion around the focal point and Raman signal is focused on the focal plane of the sample .

In this case, if it is used to cross the excitation light sources of the wavelengths ranging from the ultraviolet to the near-infrared rays over a wide area, the lenses are optimized in an arbitrary reference wavelength light source due to the color aberration of the lenses. The performance of the Raman optical signal deteriorates with respect to the resolution and the signal-to-noise ratio.

If an excitation light source is used that is far from the arbitrary wavelength thus optimized, the chromatic aberration lens (achromatic lens) is also limited.

Generally, a Raman spectrometer is equipped with a spectrograph to obtain a Raman spectrum. The spectroscope has reproducibility within a certain range of wavelength position.

This means that if you measure different spectral intervals, then the position of the calibrated wavelength is fluctuating within the range of its reproducibility values.

Therefore, in many current Raman spectroscopy systems, wavelength correction is performed on the spectroscope before obtaining Raman spectra in different spectral ranges.

However, there is still a problem that such pre-correction still obtains a shaken spectrum within the range of the reproducibility value.

Therefore, in many fields, it is required to have a Raman system that can acquire the spectra that these wavelength compensation is automatically performed at the same time as the measurement.

Korean Patent Publication No. 10-2008-0031829 (published on Apr. 11, 2008) Korean Patent Publication No. 10-2011-0015666 (published on February 16, 2011) Korean Patent Publication No. 10-2012-0135438 (published on December 13, 2012)

In order to solve the above problems, an object of the present invention is to provide an excitation light source for illuminating excitation light sources on a sample, collecting Raman scattering optical signals or fluorescence signals, Channel excitation light source switching micro-Raman and fluorescence spectroscopic analysis apparatus which can remove chromatic aberration and cross excitation light sources having a wide range of wavelengths.

A further problem of the present invention is that a reference line peak spectrum lamp light source with a spectrometer and a Raman spectrometer and a fluorescence spectrometry chamber from a spectrometer are used in order to obtain a wavelength- Micro Raman for switching the multi-channel excitation light source capable of obtaining a Raman or fluorescence spectrum in which the wavelength axis of the two-dimensional detector (CCD) is corrected based on the line spectra simultaneously with the measurement, And a fluorescence spectrometer.

According to an aspect of the present invention, there is provided an illumination system including at least one excitation laser source, a first reflector reflecting an excitation light source emitted from the excitation laser source, an excitation light source reflecting a predetermined angle through the first reflector, A first pinhole through which the excitation light source reflected by the first parabolic mirror passes, a beam splitter through which the excitation light source passes through the first pinhole, and an excitation light source refracted by the beam splitter, A second parabolic mirror that reflects an excitation light source reflected by the second parabolic mirror, an objective lens that is incident on the excitation light source reflected by the second reflector and is irradiated onto the sample, and a second parabolic mirror that is collected through the objective lens Scattered light or fluorescence is reflected on the second parabolic mirror, and the scattered light or fluorescence, which is transmitted through the beam splitter, A third parabolic mirror through which the scattered light or fluorescence is spatially removed through the second pinhole, the third parabolic mirror being reflected by the third parabolic mirror in a parallel light form and passing only Raman scattered light or fluorescence from the light, A third reflector that selectively reflects Raman scattered light or fluorescence that has passed through the filter, and fourth and fifth parabolic mirrors that selectively reflect Raman scattered light or fluorescence by the third reflector.

A first parabolic mirror for reflecting an excitation light source reflected at a predetermined angle through the first reflector; a second parabolic mirror for reflecting the excitation light source at a predetermined angle; A first pinhole through which the excitation light source reflected by the first parabolic mirror passes, a color selection mirror through which the excitation light source passes through the first pinhole, a second parabolic mirror through which the excitation light source refracted by the color selection mirror reflects, A second reflector that reflects an excitation light source reflected from the second parabolic mirror, an objective lens that is incident on the excitation light source reflected by the second reflector and is irradiated on the sample, and a scattered light Or fluorescent light is reflected on the second parabolic mirror, and the scattered light or fluorescence that is transmitted through the color selection mirror and passes through the second pinhole, A third parabolic mirror through which the noise is spatially removed through the second pinhole, the third parabolic mirror reflecting the fluorescence, and the parabolic mirror reflected by the third parabolic mirror so as to remove the wavelength of the excitation light source, A third reflector selectively reflecting only Raman scattered light or fluorescence passing through the filter, and fourth and fifth parabolic mirrors reflecting Raman scattered light or fluorescence signals selectively reflected by the third reflector, .

And the objective lens is a reflective objective lens.

The filter may be at least one or more.

Wherein the filter is one of a long pass edge filter and a notch filter.

In the present invention, excitation light sources of wavelengths ranging over a wide area can be used by crossing excitation light sources, Raman scattering light signals or fluorescence signals, and non-spherical mirrors for producing parallel light, thereby removing chromatic aberration It is effective.

Also, in order to obtain a wavelength-corrected spectrum in real time, the present invention includes a lamp light source having a reference line spectrum and an output Raman optical signal or fluorescence signals obtained from Raman and fluorescence spectroscopic analysis chambers are spatially separated The Raman spectrum or the fluorescence spectrum in which the wavelength axis of the two-dimensional detector is corrected based on the line spectra can be obtained simultaneously with the measurement.

BRIEF DESCRIPTION OF THE DRAWINGS The accompanying drawings, which are incorporated in and constitute a part of the specification, illustrate preferred embodiments of the invention and, together with the description, serve to further the understanding of the technical idea of the invention, And shall not be construed as interpretation.
BRIEF DESCRIPTION OF THE DRAWINGS Figure 1 is an illustration of a conventional micro-Raman spectroscopic device,
FIGS. 2 to 4 are views illustrating micro-Raman and fluorescence spectrometry apparatuses for switching a multi-channel excitation light source according to an embodiment of the present invention.

Hereinafter, preferred embodiments of a micro-Raman and fluorescence spectrometer for switching a multi-channel excitation light source according to the present invention will be described in detail with reference to the accompanying drawings.

FIGS. 2 to 4 are views illustrating micro-Raman and fluorescence spectrometry apparatuses for switching a multi-channel excitation light source according to an embodiment of the present invention.

2 to 4, the micro-Raman and fluorescence spectrometer for switching a multi-channel excitation light source according to a preferred embodiment of the present invention includes an excitation laser source 10, a first reflector 20, a first parabolic mirror A second pinhole 90 and a third parabolic mirror 100. The first parallax mirror 30 and the second parallax mirror 30 are fixed to the first pinhole 40 and the beam splitter 50, A filter 110, a third reflector 120, a fourth parabolic mirror 130, and a fifth parabolic mirror 140, which will be described in detail as follows.

3 is a view for explaining the structure of collecting Raman scattered light or fluorescence reflected from a sample and irradiating the excitation light source to the sample.

The excitation laser sources 10 have different wavelengths, and a plurality of excitation laser sources 10 are provided.

The first reflector 20 selectively reflects an excitation light source selectively emitted from the excitation laser source 10.

The excitation light source reflected by the first reflector 20 at a predetermined angle is randomly removed from the intensity profile and the first parabolic mirror 30 And a first pinhole 40 are provided.

The beam splitter 50 or the color discriminating mirror 50 'reflects the excitation light source, and at the same time, scattered or fluoresced from the sample, and scattered light or fluorescence passing through the objective lens 80 is passed.

At this time, if a reflective objective lens is used instead of a general transmissive objective lens, a micro-Raman and a fluorescence system using an entirely reflective mirror can be realized.

FIG. 2 is a view for explaining a structure for placing the excitation light source at an arbitrary position of the sample. When parallel light is generated by the second parabolic mirror 60, image observation of the sample, focus of the excitation light source And a pair of beam splitters and a CCD camera for positioning the focus at an appropriate position while simultaneously focusing the excitation light source on the sample and the sample.

The second pinhole 90 removes these focal lights at conjugate Raman scattering or in the confocal position of fluorescence.

The third parabolic mirror 100 is provided with at least one long pass edge filter and a notch filter to generate scattered light or fluorescence as parallel light and to remove the excitation light source.

Meanwhile, an optical fiber type or a free space type is selected for the third reflector 120 to input Raman scattering light or fluorescence into the spectroscope.

That is, in the case of using the optical fiber type, a fourth parabolic mirror 130 in which matching is considered for introducing Raman or a fluorescence signal into the optical fiber is used.

In the case of using the free space type, a fifth parabolic mirror 140 considering matching of the spectroscope is used.

While the present invention has been described in connection with what is presently considered to be practical exemplary embodiments, it is to be understood that the invention is not limited to the disclosed embodiments, but, on the contrary, And such variations and modifications are intended to fall within the scope of the appended claims.

10: here laser source
20: First mirror
30: 1st parabolic mirror
40: first pinhole
50: beam splitter
50 ': Color selection mirror
60: The second parabolic mirror
70: Second reflector
80: Objective lens
90: second pinhole
100: The third parabolic mirror
110: filter
120: Third reflector
130: The fourth parabolic mirror
140: The fifth parabolic mirror

Claims (5)

At least one excitation laser source (10);
A first reflector (20) reflecting an excitation light source emitted from the excitation laser source (10);
A first parabolic mirror 30 reflecting an excitation light source reflected at a predetermined angle through the first reflector 20;
A first pinhole (40) through which an excitation light source reflected by the first parabolic mirror (30) passes;
A beam splitter (50) through which the excitation light source passed through the first pinhole (40) is refracted;
A second parabolic mirror (60) reflecting the excitation light source refracted by the beam splitter (50);
A second reflector (70) reflecting the excitation light source reflected by the second parabolic mirror (60);
An objective lens 80 to which an excitation light source reflected by the second reflector 70 is incident and is irradiated onto the sample;
The Raman scattering light or fluorescence collected through the objective lens 80 is reflected by the second parabolic mirror 60 and passes through the beam splitter 50 to pass through the second pinhole 90);
A third parabolic mirror 100 through which the Raman scattered light or fluorescence is spatially reflected by passing through the second pinhole 90;
A filter 110 which is reflected by the third parabolic mirror 100 in a parallel light form to pass only Raman scattering light or fluorescence signals with the elimination of the wavelength of the excitation light source;
A third reflector 120 selectively reflecting only Raman scattered light or fluorescence having passed through the filter 110; And
And fourth and fifth parabolic mirrors (130, 140) selectively reflecting Raman scattering light or fluorescence reflected by the third reflector (120). At least one excitation laser source (10);
A first reflector (20) reflecting an excitation light source emitted from the excitation laser source (10);
A first parabolic mirror 30 reflecting an excitation light source reflected at a predetermined angle through the first reflector 20;
A first pinhole (40) through which an excitation light source reflected by the first parabolic mirror (30) passes;
A color selecting mirror 50 'through which the excitation light source having passed through the first pinhole 40 is reflected;
A second parabolic mirror 60 for reflecting the excitation light source refracted by the color discriminating mirror 50 ';
A second reflector (70) reflecting the excitation light source reflected by the second parabolic mirror (60);
An objective lens 80 to which an excitation light source reflected by the second reflector 70 is incident and is irradiated onto the sample;
The Raman scattering light or fluorescence emitted and collected by the sample through the objective lens 80 is reflected by the second parabolic mirror 60 and the Raman scattering light or fluorescence emitted through the color selecting mirror 50 ' A second pinhole 90 passing therethrough;
A third parabolic mirror 100 through which the Raman scattered light or fluorescence is spatially reflected by passing through the second pinhole 90;
A filter 110 which is reflected by the third parabolic mirror 100 in a parallel light form to pass only Raman scattering light or fluorescence signals with the elimination of the wavelength of the excitation light source;
A third reflector 120 selectively reflecting only Raman scattered light or fluorescence having passed through the filter 110; And
And fourth and fifth parabolic mirrors (130, 140) selectively reflecting Raman scattering light or fluorescence reflected by the third reflector (120). 3. The method according to claim 1 or 2,
And the objective lens (80) is a reflection type objective lens. The multi-channel excitation light source switching micro-Raman and fluorescence spectroscopy analyzing apparatus. 3. The method according to claim 1 or 2,
The micro-Raman and fluorescence spectrometer for switching a multi-channel excitation light source comprises at least one filter (110). 5. The method of claim 4,
Wherein the filter (110) is one of a long-pass edge filter and a notch filter.

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