CN207007716U - Dual-wavelength laser Raman spectrometer - Google Patents

Dual-wavelength laser Raman spectrometer Download PDF

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CN207007716U
CN207007716U CN201720809001.XU CN201720809001U CN207007716U CN 207007716 U CN207007716 U CN 207007716U CN 201720809001 U CN201720809001 U CN 201720809001U CN 207007716 U CN207007716 U CN 207007716U
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raman
wavelength
dual
mirror
aotf
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万雄
万嘉杰
章炜毅
王建宇
殷海玮
王泓鹏
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Shanghai Institute of Technical Physics of CAS
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Shanghai Institute of Technical Physics of CAS
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Abstract

This patent discloses a kind of dual-wavelength laser Raman spectrometer, the instrument includes master controller, Raman spectrometer, super continuous spectrums laser and dual wavelength Raman probe.Wherein, dual wavelength Raman probe is by launching fiber, reception optical fiber, transmitting beam expanding lens;The complementary narrow pass filter of rf control unit, AOTF, Multicolour mirror, convergent mirror, total reflective mirror, AOTF complementations arrowband resistance-trap filter and fibre-coupled mirrors composition.The beneficial effect of this patent is, complementary acousto-optic tunable filter is applied into dual wavelength Raman probe, and use super continuous spectrums laser and same spectrometer, realize the multiplexing of source and rear end, dual wavelength and the detection of continuous wavelength Raman can be effectively realized, to solve the interference of Raman fluorescence, improve Raman detection effect and provide solution.

Description

Dual-wavelength laser Raman spectrometer
Technical field
This patent is related to a kind of laser spectrum detection system, more particularly to a kind of instrument using dual-wavelength laser Raman detection Device, detected suitable for the molecular chaperones of material, belong to photodetection field.
Background technology
In LR laser raman detection, excitation laser in target in addition to inspiring discrete Raman scattering spectral line, also The part of continuous radiation being present, i.e. fluorescent scattering is disturbed, and in some cases, hyperfluorescence background can have a strong impact on Raman signal, Raman signal even is hidden, causes the degradation of LR laser raman Detection results.
Raman emission is distinguished using the laser of two close wavelength of wavelength, fluorescence is then eliminated by calculus of differences Continuous radiation is a method for preferably suppressing to eliminate fluorescence.Independent dual wavelength system complexity when structure increases Add twice, efficiency is low.How efficiently and rapidly to realize dual-wavelength laser Raman detection is a urgent need to solve the problem.
This patent is directed to the problem, proposes a kind of instrument for efficiently and rapidly realizing dual-wavelength laser Raman detection and side Method, complementary acousto-optic tunable filter is applied into dual wavelength Raman probe, and use super continuous spectrums laser and same spectrum Instrument, the multiplexing of source and rear end is realized, the instrument and method can effectively realize dual wavelength Raman detection, and can be easily real Now continuous wavelength Raman detection, to solve the interference of Raman fluorescence, improve Raman detection effect and provide solution.
The content of the invention
The purpose of this patent is to provide a kind of instrument and method for efficiently and rapidly realizing dual-wavelength laser Raman detection, By being multiplexed the portability and ease for use of increase instrument, to solve traditional Single wavelength LR laser raman fluorescence interference problem.
This patent is achieved like this:
Dual wavelength Raman spectrometer mainly includes master controller, Raman spectrometer, super continuous spectrums laser and dual wavelength and drawn Graceful probe.
Wherein, dual wavelength Raman probe is complementary by launching fiber, reception optical fiber, transmitting beam expanding lens, rf control unit, AOTF Narrow pass filter, Multicolour mirror, convergent mirror, total reflective mirror, AOTF complementations arrowband resistance-trap filter and fibre-coupled mirrors composition;
There is main control software in master controller, for being controlled to super continuous spectrums laser, rf control unit, and pass through USB interface is powered and received to Raman spectrometer and analyzes its output spectrum signal;
Super continuous spectrums laser is connected by SMA interfaces with launching fiber;Raman spectrometer is connect with reception optical fiber by SMA Mouth connection;
It is parallel with receiving optical axis to launch optical axis, target detection point is on transmitting optical axis;
Dual wavelength Raman spectrometer works according to the following steps:
(1) dual wavelength Raman signal obtains
Master controller 3 sends control instruction and starts rf control unit, the passband ripple of the complementary narrow pass filters of setting AOTF A length of λ1, the sunken bandgap wavelength of AOTF complementations arrowband resistance-trap filter is also λ1
Master controller sends control instruction and starts super continuous spectrums laser, and the super continuous spectrums that super continuous spectrums laser is sent swash Light is transmitted by launching fiber, is advanced after transmitting beam expanding lens is expanded along transmitting optical axis, by the complementary narrow passbands of AOTF Wavelength is changed into λ after wave filter narrow-band filtering1, through Multicolour mirror, concentrated mirror focuses to target detection point;
The Raman echo signal of target detection point returns along transmitting optical axis, through convergent mirror, after Multicolour mirror reflects, towards complete Anti- mirror is advanced, then receives optical axis through total reflective mirror reflection rear steering, is filtered through AOTF complementations arrowband resistance-trap filter Rayleigh, is removed wavelength For λ1Transmitting echo composition after, remaining Raman signal converges to reception optical fiber end face through fibre-coupled mirrors, subsequently into connecing Inside of optical fibre transmission is received, enters back into Raman spectrometer, by grating beam splitting, the excitation wavelength after opto-electronic conversion is λ1Raman light Modal data is sent into master controller and carries out storage analysis;
Master controller sends control instruction and starts rf control unit, the passband wavelength of the complementary narrow pass filters of setting AOTF For λ2, the sunken bandgap wavelength of AOTF complementations arrowband resistance-trap filter is also λ2
Now, the super continuous spectrums laser that super continuous spectrums laser is sent is transmitted by launching fiber, by launching beam expanding lens Advanced after being expanded along transmitting optical axis, wavelength is changed into λ after the complementary narrow pass filter narrow-band filterings of AOTF2, through more Look mirror, concentrated mirror focus to target detection point;
The Raman echo signal of target detection point returns along transmitting optical axis, through convergent mirror, after Multicolour mirror reflects, towards complete Anti- mirror is advanced, then receives optical axis through total reflective mirror reflection rear steering, is filtered through AOTF complementations arrowband resistance-trap filter Rayleigh, is removed wavelength For λ2Transmitting echo composition after, remaining Raman signal converges to reception optical fiber end face through fibre-coupled mirrors, subsequently into connecing Inside of optical fibre transmission is received, enters back into Raman spectrometer, by grating beam splitting, the excitation wavelength after opto-electronic conversion is λ2Raman light Modal data is sent into master controller and carries out storage analysis;
(2) dual wavelength Raman signal is handled
The analysis software program of master controller is analyzed the dual wavelength Raman spectrum data of collection according to the following steps:
A. area normalization
By λ1Raman spectrum data and λ2The area that is surrounded below by the curve of spectrum of Raman spectrum data be normalized Computing, obtain λ1Normalization Raman spectrum data and λ2Normalization Raman spectrum data;
B. calculus of differences
By λ1Normalization Raman spectrum data subtract λ2Normalization Raman spectrum data;Eliminate interference and the shadow of fluorescence Ring, that is, eliminate curve continuous fluorescence base part;
C. computing is blocked
By the later spectroscopic data of difference along λ2Position is blocked;
D. inverting op
Later spectroscopic data will be blocked and negated (reversion) computing;
E. positive computing is taken
Spectroscopic data after inverting op is carried out to take positive computing, eliminates negative spectrum intensity data;
F. Raman frequency shift is changed
The abscissa for taking the spectroscopic data after positive computing is converted into wave number cm by wavelength X-1, and and λ2Corresponding wavelength phase Subtract, obtain Raman frequency shift.
The beneficial effect of this patent is complementary acousto-optic tunable filter to be applied into dual wavelength Raman probe, and use Super continuous spectrums laser and same spectrometer, realize the multiplexing of source and rear end, can effectively realize dual wavelength and continuous more ripples Long Raman detection, to solve the interference of Raman fluorescence, improve Raman detection effect and provide solution.
Brief description of the drawings
The dual wavelength Raman spectrometer structural representation that Fig. 1 designs for this patent, Fig. 2 are that the signal transacting of this patent is illustrated Scheme, in figure:1 --- Raman spectrometer;2 --- super continuous spectrums laser;3 --- master controller;4 --- launching fiber;5—— Reception optical fiber;6 --- transmitting beam expanding lens;7 --- rf control unit;8 --- the complementary narrow pass filters of AOTF;9 --- polychrome Mirror;10 --- convergent mirror;11 --- target detection point;12-transmitting optical axis;13 --- receive optical axis;14 --- dual wavelength Raman Probe;15 --- total reflective mirror;16 --- AOTF complementations arrowband resistance-trap filter;17 --- fibre-coupled mirrors.
Note:AOTF, acousto-optic tunable filter, i.e. acousto-optic tunable filter.
Embodiment
This patent embodiment is as depicted in figs. 1 and 2.
As shown in figure 1, this patent design dual wavelength Raman spectrometer mainly include master controller 3, Raman spectrometer 1, Super continuous spectrums laser 2 and dual wavelength Raman probe 14.
Wherein, dual wavelength Raman probe 14 by launching fiber 4, reception optical fiber 5, transmitting beam expanding lens 6, rf control unit 7, AOTF complementary narrow pass filter 8, Multicolour mirror 9, convergent mirror 10, total reflective mirror 15, AOTF complementations arrowband resistance-trap filter 16 and optical fiber Coupling mirror 17 forms;
Have main control software in master controller 3, for super continuous spectrums laser 2, rf control unit 7, pass through USB interface pair Raman spectrometer 1 is powered and received and analyzes its output spectrum signal;
Super continuous spectrums laser 2 is connected by SMA interfaces with launching fiber 4;Raman spectrometer 1 passes through with reception optical fiber 5 SMA interfaces connect;
It is parallel with receiving optical axis 13 to launch optical axis 12, target detection point 11 is on transmitting optical axis 12;
Dual wavelength Raman spectrometer works according to the following steps:
(1) dual wavelength Raman signal obtains
Master controller 3 sends control instruction and starts rf control unit 7, the passband of the complementary narrow pass filters 8 of setting AOTF Wavelength is λ1, the sunken bandgap wavelength of AOTF complementations arrowband resistance-trap filter 16 is also λ1;(the present embodiment λ1Take 785nm)
It is (near for 750nm-1250nm in the present embodiment that master controller 3 sends control instruction startup super continuous spectrums laser 2 The fiber optic supercontinuum laser of infrared repetition 2MHz pulsewidth picosecond magnitudes), the super continuous spectrums that super continuous spectrums laser 2 is sent swash Light is transmitted by launching fiber 4, is advanced after transmitting beam expanding lens 6 is expanded along transmitting optical axis 12, narrow by AOTF complementations Wavelength is changed into λ after the narrow-band filtering of pass filter 81, through Multicolour mirror 9, concentrated mirror 10 focuses to target detection point 11;
The Raman echo signal of target detection point 11 returns along transmitting optical axis 12, through convergent mirror 10, is reflected through Multicolour mirror 9 Afterwards, advanced towards total reflective mirror 15, then reflect rear steering through total reflective mirror 15 and receive optical axis 13, it is auspicious through AOTF complementations arrowband resistance-trap filter 16 Profit filtering, removal wavelength is λ1Transmitting echo composition after, remaining Raman signal converges to reception light through fibre-coupled mirrors 17 Fine 5 end faces, subsequently into the internal transmission of reception optical fiber 5, enter back into Raman spectrometer 1, by grating beam splitting, after opto-electronic conversion Excitation wavelength is λ1Raman spectrum data be sent into master controller 3 carry out storage analysis;
Master controller 3 sends control instruction and starts rf control unit 7, the passband of the complementary narrow pass filters 8 of setting AOTF Wavelength is λ2, the sunken bandgap wavelength of AOTF complementations arrowband resistance-trap filter 16 is also λ2;(the present embodiment λ2Take 830nm)
Now, the super continuous spectrums laser that super continuous spectrums laser 2 is sent is transmitted by launching fiber 4, is expanded by transmitting Mirror 6 is advanced after being expanded along transmitting optical axis 12, and wavelength is changed into λ after the complementary narrow narrow-band filterings of pass filter 8 of AOTF2, Through Multicolour mirror 9, concentrated mirror 10 focuses to target detection point 11;
The Raman echo signal of target detection point 11 returns along transmitting optical axis 12, through convergent mirror 10, is reflected through Multicolour mirror 9 Afterwards, advanced towards total reflective mirror 15, then reflect rear steering through total reflective mirror 15 and receive optical axis 13, it is auspicious through AOTF complementations arrowband resistance-trap filter 16 Profit filtering, removal wavelength is λ2Transmitting echo composition after, remaining Raman signal converges to reception light through fibre-coupled mirrors 17 Fine 5 end faces, subsequently into the internal transmission of reception optical fiber 5, enter back into Raman spectrometer 1, by grating beam splitting, after opto-electronic conversion Excitation wavelength is λ2Raman spectrum data be sent into master controller 3 carry out storage analysis;
(2) dual wavelength Raman signal is handled
The analysis software program of master controller 3 is analyzed the dual wavelength Raman spectrum data of collection according to the following steps, As shown in Figure 2:
A. area normalization
By λ1Raman spectrum data and λ2The area that is surrounded below by the curve of spectrum of Raman spectrum data be normalized Computing, obtain λ1Normalization Raman spectrum data and λ2Normalization Raman spectrum data;
B. calculus of differences
By λ1Normalization Raman spectrum data subtract λ2Normalization Raman spectrum data;Eliminate interference and the shadow of fluorescence Ring, that is, eliminate curve continuous fluorescence base part;
C. computing is blocked
By the later spectroscopic data of difference along λ2Position is blocked;
D. inverting op
Later spectroscopic data will be blocked and negated (reversion) computing;
E. positive computing is taken
Spectroscopic data after inverting op is carried out to take positive computing, eliminates negative spectrum intensity data;
F. Raman frequency shift is changed
The abscissa for taking the spectroscopic data after positive computing is converted into wave number cm by wavelength X-1, and and λ2Corresponding wavelength phase Subtract, obtain Raman frequency shift.

Claims (1)

1. a kind of dual-wavelength laser Raman spectrometer, including master controller (3), Raman spectrometer (1), super continuous spectrums laser And dual wavelength Raman probe (14) (2), it is characterised in that:
Dual wavelength Raman probe (14) by launching fiber (4), reception optical fiber (5), transmitting beam expanding lens (6), rf control unit (7), The complementary narrow pass filters (8) of AOTF, Multicolour mirror (9), convergent mirror (10), total reflective mirror (15), AOTF complementations arrowband resistance-trap filter (16) formed with fibre-coupled mirrors (17);
There is main control software in master controller (3), for being controlled to super continuous spectrums laser (2), rf control unit (7), and Raman spectrometer (1) is powered and received by USB interface and analyzes its output spectrum signal;
Super continuous spectrums laser (2) is connected by SMA interfaces with launching fiber (4);Raman spectrometer (1) and reception optical fiber (5) Connected by SMA interfaces;
It is parallel with receiving optical axis (13) to launch optical axis (12), target detection point (11) is on transmitting optical axis (12).
CN201720809001.XU 2017-01-06 2017-07-06 Dual-wavelength laser Raman spectrometer Active CN207007716U (en)

Applications Claiming Priority (2)

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CN2017200151072 2017-01-06
CN201720015107 2017-01-06

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Cited By (2)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
CN107167465A (en) * 2017-01-06 2017-09-15 中国科学院上海技术物理研究所 A kind of dual-wavelength laser Raman spectrometer
CN111638203A (en) * 2020-07-16 2020-09-08 江苏天瑞仪器股份有限公司 Dual-wavelength laser confocal detection method of Raman probe

Cited By (2)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
CN107167465A (en) * 2017-01-06 2017-09-15 中国科学院上海技术物理研究所 A kind of dual-wavelength laser Raman spectrometer
CN111638203A (en) * 2020-07-16 2020-09-08 江苏天瑞仪器股份有限公司 Dual-wavelength laser confocal detection method of Raman probe

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