CN209264563U - A kind of refractive index micrometering system - Google Patents
A kind of refractive index micrometering system Download PDFInfo
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- CN209264563U CN209264563U CN201821461683.0U CN201821461683U CN209264563U CN 209264563 U CN209264563 U CN 209264563U CN 201821461683 U CN201821461683 U CN 201821461683U CN 209264563 U CN209264563 U CN 209264563U
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Abstract
The utility model is suitable for optical field, provide a kind of refractive index micrometering system, including detecting light generating device, scanning probe device and Signal acquiring and processing device, wherein, detection light generating device is used to provide the detection light with tightly focused characteristic, and detection light is incident to scanning probe device, scanning probe device focuses on the detection light in sample strip, for being scanned to sample strip to generate experiment optical signal, and experiment optical signal is incident to Signal acquiring and processing device, it include the refractive index information of sample strip in the experiment optical signal, Signal acquiring and processing device is for acquiring experiment optical signal, and collected experiment optical signal is carried out including photoelectric conversion, after the processing of denoising and information extraction, obtain the refractive index information of sample strip.For refractive index micrometering system provided by the utility model when carrying out refractometry, measurement accuracy is high.
Description
Technical field
The utility model relates to optical field more particularly to a kind of refractive index micrometering systems.
Background technique
Biological cell is the structural unit of life entity and the basic unit of vital movement, cellular morphology and refractive index
It is distributed closely related with the function of biological cell.The development of optical microscopy imaging technology is greatly promoted people to microcosmic life
Phenomenon and essence exploration, from early stage can only from cell still image can study by now the dynamic in living cells become
Change, scientists have paid unremitting effort thus, and diversified precision optics is microscopical universal so that subcellular scale
Cell exploration become universal.Wherein, the research for being absorbed in the refractive index imaging of cell and subcellular structure has unmarked, nothing
It damages in the cell the advantages that, receives the extensive concern of researchers.
The refractive index of measurement cell can not only obtain the important informations such as biochemical composition, activity and the function of cell, and
Reference data can be provided for medical diagnosis and drug research.But in existing cell micrometering technology, cell folding
The precision for penetrating rate measurement is not high.
Utility model content
The utility model provides a kind of refractive index micrometering system, can be used for solving the prior art and is carrying out cell inspection
When survey, the not high problem of the measurement accuracy of cellular refractive index.
Refractive index micrometering system provided by the utility model include: detection light generating device, scanning probe device and
Signal acquiring and processing device;
The detection light generating device, for providing the detection light with tightly focused characteristic, and the detection light is incident
To the scanning probe device;
The scanning probe device focuses on the detection light in sample strip, for the sample strip be scanned with
Experiment optical signal is generated, and the experiment optical signal is incident to the Signal acquiring and processing device, the experiment optical signal
In include the sample strip refractive index information;
The Signal acquiring and processing device is carried out for acquiring the experiment optical signal, and to the experiment optical signal
After photoelectric conversion, denoising and the processing of information extraction, the refractive index information of the sample strip is obtained.
Compared with prior art, beneficial effect is the utility model: since detection light has tightly focused characteristic, detecting light
For tightly focused hot spot being formed on the surface of sample strip, due to reducing spot size, to mention when scanning sample strip after focusing
High resolution ratio.Also, the faint experiment optical signal that Signal acquiring and processing device can generate during acquisition scans, and lead to
It crosses photoelectric conversion to record the mode for the refractive index information electric signal tested in optical signal, then filter out in the electric signal
Noise to improve signal-to-noise ratio, to be exaggerated measured signal relevant to refractive index, improve the measurement accuracy of refractive index.
Detailed description of the invention
It, below will be in the utility model in order to illustrate more clearly of technical solution provided by the embodiment of the utility model
Required attached drawing is briefly described, it should be apparent that, the accompanying drawings in the following description is only the one of the utility model
A little embodiments for those skilled in the art without creative efforts, can also be according to these attached drawings
Obtain other attached drawings.
Fig. 1 is the structural schematic diagram for the refractive index micrometering system that the utility model first embodiment provides;
Fig. 2 is the Signal acquiring and processing dress in the refractive index micrometering system that the utility model second embodiment provides
The structural schematic diagram set;
Fig. 3 is the detailed construction schematic diagram for the refractive index micrometering system that the utility model second embodiment provides.
Specific embodiment
It is practical below in conjunction with this to enable the purpose of this utility model, feature, advantage more obvious and understandable
Attached drawing in new embodiment, the technical scheme in the utility model embodiment is clearly and completely described, it is clear that institute
The embodiment of description is only the utility model a part of the embodiment, and not all embodiments.Based on the reality in the utility model
Apply example, those skilled in the art's every other embodiment obtained without making creative work belongs to this
The range of utility model protection.
Referring to Fig. 1, the schematic diagram of the refractive index micrometering system provided for the utility model first embodiment.
Refractive index micrometering system provided by the embodiment of the utility model includes: detection light generating device 100, scanning spy
Survey device 200 and Signal acquiring and processing device 300.
Detection light generating device 100 is used to provide the detection light with tightly focused characteristic, and detection light is incident to scanning
Detection device 200.
Scanning probe device 200 focuses on light is detected in sample strip, for being scanned to sample strip to generate experiment
Optical signal, and experiment optical signal is incident to Signal acquiring and processing device 300, it include sample strip in the experiment optical signal
Refractive index information.
Signal acquiring and processing device tests optical signal for acquiring, and includes to collected experiment optical signal
After photoelectric conversion, denoising and the processing of information extraction, the refractive index information of sample strip is obtained.
In the utility model embodiment, since detection light has tightly focused characteristic, focusing of the detection light in condenser lens
Point light source is formed under effect, point light source has many advantages, such as that high directivity, the small and brightness of diverging are high, and therefore, which is incident upon
In sample strip, form the excitation hot spot of overall size very little, the size of the diameter of the excitation hot spot and sample unit quite or
It is smaller, for being scanned to sample strip.
It should be noted that in a certain range, excitation hot spot is smaller, and the spatial resolution of micrometering system is better.
Resolution ratio is the important performance indexes of micrometering system, and the size of resolution ratio is indicated with the numerical value of resolution distance, should
Resolution distance is the minimum range between two object points that can be differentiated open.Resolution distance is smaller, indicates that resolution ratio is higher, surveys
It measures more accurate.
Illustratively, which can be circularly polarized light, elliptically polarized light, angularly polarized light or radial polarisation light etc..
By taking cell sample piece as an example, optical scanning cell sample piece is detected, and reflect on the surface of the cell sample piece,
And the relevant information of cell to be measured is carried in reflected light, which is the experiment light letter of formation during scanning probe
Number.In colon epidermal cell sample strip, due to cancerous tumor cell and normal cell form, size and in terms of not
Together, cause the refractive index of the cell membrane of cancerous tumor cell and the refractive index of the cell membrane of normal cell to have differences, therefore, detect light
Scanning colon epidermal cell sample strip is formed by experiment optical signal, and the optical power at different scanning point has differences, so that
Experiment optical signal carries the refractive index information of colon epidermal cell sample strip.
In the utility model embodiment, Signal acquiring and processing device 300 can be used for acquiring during detection optical scanning
The faint experiment optical signal generated, due to including the refractive index information of sample strip in the experiment optical signal, by right
The experiment optical signal carries out in the electric signal obtained after photoelectric conversion, also includes the refractive index information of sample strip.Signal acquisition
It is also used to filter out the noise signal unrelated with the refractive index information of sample strip in the electric signal with processing unit 300, to put
Measured signal in the big electric signal, handles finally by the electric signal after denoising, extracts from the measured signal
Refractive index information obtains the index distribution situation of sample strip.In above process, due to eliminating the interference of noise signal,
Signal-to-noise ratio is improved, so that the measurement accuracy of refractive index is improved, thus the spirit for the refractive index information extracted in the present embodiment
Sensitivity is high.
In the utility model embodiment, for scanning sample after due to detection light there is tightly focused characteristic, detection light to focus
When product piece, tightly focused hot spot is formed on the surface of sample strip, due to reducing spot size, to improve resolution ratio.Also,
The faint experiment optical signal that Signal acquiring and processing device can generate during acquisition scans, and will be tested by photoelectric conversion
The mode of refractive index information electric signal in optical signal is recorded, and filters out the noise in the electric signal then to improve noise
Than improving the measurement accuracy of refractive index.
Referring to Fig. 2, the signal acquisition in the refractive index micrometering system provided for the utility model second embodiment
With the structural schematic diagram of processing unit.
Signal acquiring and processing device 300 includes photodetector 301, lock-in amplifier 302 and computer control system
303.Wherein, the input terminal of lock-in amplifier 302 is connect with the output end of photodetector 301, the output of lock-in amplifier 302
End is connect with computer control system 303.
Collected experiment optical signal for acquiring experiment optical signal, and is converted to corresponding electricity by photodetector 301
Output is to lock-in amplifier 302 after signal.
Lock-in amplifier 302 is exported for receiving electric signal, and after carrying out denoising to the electric signal received to meter
Calculate machine control system 303.
Computer control system 303 for receiving the electric signal after denoising, and extracts sample from the electric signal after denoising
The refractive index information of piece.
In the utility model embodiment, photodetector 301 can be photodiode, avalanche optoelectronic pipe or photoelectricity times
Increase pipe etc..The input terminal of photodetector 301 can be used for acquiring the faint experiment optical signal generated during optical detection, due to
Include the refractive index information of sample strip in the experiment optical signal, therefore, the experiment optical signal is carried out in photodetector 301
It also include the refractive index information of sample strip in the electric signal obtained after photoelectric conversion, photodetector 301 passes through its output end
By the electric signal transmission to lock-in amplifier 302.
The input terminal of lock-in amplifier 302 includes noise signal and and sample in the electric signal for receiving the electric signal
The relevant measured signal of the refractive index information of piece filters out this by corresponding operation in the working frequency of lock-in amplifier 302
The noise signal unrelated with the refractive index information of sample strip in electric signal, eliminates the interference of noise signal, so that amplification should
Measured signal in electric signal improves signal-to-noise ratio, improves the measurement accuracy of refractive index.Lock-in amplifier 302 passes through its input terminal
By the electric signal transmission after denoising to computer control system 303.
Computer control system 303 is used to carry out simulation based on digital processing to the electric signal after denoising, from the measured signal
Middle extraction refractive index information obtains the index distribution situation of sample strip, so that the refractive index to sample strip is quantified or is determined
Property analysis.
Referring to Fig. 3, the detailed construction of the refractive index micrometering system provided for the utility model second embodiment is shown
It is intended to.
Detection light generating device 100 includes setting gradually in optical path: laser 101, chopper 102, space light modulation
Device 103, the polarizer 104, concavees lens group 105, half wave plate 106, vortex wave plate 107 and spiral phase plate 108.
Wherein, laser 101, for providing the continuous laser of preset wavelength.
Chopper 102, for the continuous laser of the preset wavelength to be modulated into the laser signal with fixed frequency.
Spatial light modulator 103, for there is the laser signal of fixed frequency to be modulated into annular beam this.
The polarizer 104, for annular beam to be modulated into linearly polarized light.
Concavees lens group 105, for being expanded to the linearly polarized light.
Half wave plate 106, for changing the polarization direction of the linearly polarized light after expanding.
Vortex wave plate 107 forms angular polarization for carrying out phase regulation to the linearly polarized light behind change polarization direction
Light.
Spiral phase plate 108 obtains the angular polarization that topological charge values are+1 for increasing the topological charge of angularly polarized light
Light, using the angularly polarized light that the topology charge values are+1 as detection light.
In the utility model embodiment, the continuous laser for the preset wavelength that laser 101 projects is passing through chopper 102
Modulation after, export as the light pulse signal with fixed frequency, while exporting modulating frequency.Spatial light tune in the present embodiment
Device 103 processed is reflective pure phase type spatial light modulator, and annular beam refers to continuous helical shape phase front and determination
The vortex beams of orbital angular momentum, and the light intensity at the helical phase center of the vortex beams is zero.
Concavees lens group 105 includes the first concavees lens and the second concavees lens, and linearly polarized light successively passes through the first concavees lens and the
Two concavees lens expand effect after, into half wave plate 106, it is inclined that incident line is changed by the half wave plate 106
The polarization direction of vibration light, keeps it vertical with former direction, then by vortex phase on vortex slide band, and has track angular motion
Amount forms angularly polarized light, then the topological charge values of the angularly polarized light is modulated to+1 by spiral phase plate 108, it is final must
The light beam arrived is to detect light, and the detection light in the present embodiment has tightly focused characteristic.
Specifically, it being vibrated due to angularly polarized light along azimuth direction, polarization direction is centrosymmetric about optical axis, and
There is no longitudinal electric field component, therefore the projection after angularly polarized light focusing is the hollow light spot that light intensity is zero at center, it is angular inclined
Vibration light carries out the light beam formed after 0~2 π phase-modulation in spiral phase plate 108, and can be focused into profile is circular solid light
Spot.Under equal conditions, angular polarization luminous energy is obtained than linearly polarized light, radial polarisation light or the smaller focusing of circularly polarized light area
Hot spot.
Further, scanning probe device 200 includes high-NA objective 201.
The numerical aperture of high-NA objective 201 is not less than 1.49.
High-NA objective 201 scans after the detection light received is focused into point light source for receiving detection light
Sample strip 202.High-NA objective 201 is also used to collect in scanning process, and point light source is radiated at the reality generated in sample strip
Optometry signal.
It should be noted that the resolution ratio of micrometering system is determined by the resolution ratio of object lens, and high object lens
Resolution ratio is determined by the characteristic of its numerical aperture and incident light again.
The numerical aperture of object lens receives light ability, the detection light that high-NA objective 201 can be collected into for measuring it
Angular range it is bigger, receive light ability it is stronger.In the utility model embodiment, since detection light has tightly focused characteristic, visit
Survey light point light source can be formed under the focussing force of high-NA objective 201, the point light source have high directivity, diverging it is small and
The advantages that brightness is high, point light source are radiated in sample strip 202, are imaged as that symmetry is good, excitation hot spot of overall size very little, by
In the area for reducing the effective light spot being radiated in sample strip 202, so as to shorten the spatial discrimination distance of sample strip 202,
Improve imaging resolution.In a certain range, excitation hot spot is smaller, and illumination point spread function is smaller, so that in the present embodiment
The resolution ratio of high-NA objective 201 is higher, measures more accurate.
The point light source that detection light is formed after being focused by high-NA objective 201 can be used for scanning sample strip 202, detect
Light projection sample strip 202 surface and reflect, the correlation of each illuminated point of sample strip 202 is carried in reflected light
Information, the reflected light are the experiment optical signal generated in scanning process, collect the experiment light by high-NA objective 201
After signal, subsequent corresponding detection and analysis can be carried out.There is incident spy due to propagating simultaneously in high-NA objective 201
The experiment optical signal of light signal and outgoing, high-NA objective 201 use coaxial reflective-mode, reduce and absorb light and outer
The influence of portion's interference.
Further, scanning probe device 200 further includes objective table (not shown).Sample strip 202 is placed in the load
On object platform.
Computer control system 303 is connect with objective table, for controlling the movement of objective table, to realize point light source to sample
202 point by point scanning of piece.
As shown in figure 3, sample strip 202 is illuminated by white light source 203, detection light is when focusing scanning sample strip 202, institute
The excitation hot spot of formation images on same focal plane, by setting sweep parameter in computer control system 303, for controlling
Objective table processed is automatically moved along specific track, and detection light carries out the every bit in the focal plane of sample strip 202
Scanning, to obtain the experiment optical signal generated in scanning process.
Further, sample strip 202 includes graphene-based bottom and the sample to be tested being attached on graphene-based bottom.
Detection light reflects on the surface at graphene-based bottom and sample to be tested, generates experiment optical signal, and be based on graphite
The polarization absorption characteristic of alkene, the refractive index difference of sample to be tested cause the intensity for testing the S polarized light in optical signal to change.
Further, the S that the data collecting card of computer control system 303 is used to acquire and store in experiment optical signal is inclined
The intensity signal of vibration light.
Pair of the intensity signal of S polarized light and the refractive index information of sample to be tested is preserved in computer control system 303
It should be related to.
It specifically, is angularly polarized light by detection light in this present embodiment, polarization state can be expressed as S-polarization point
The vector sum of amount and P-polarization component, wherein light incident surface of the direction of S-polarization component perpendicular to optical element, P-polarization component
Direction be overlapped with the light incident surface.In the utility model embodiment, graphene-based bottom is prepared on transparent glass slide, stone
Black alkene is a kind of carbon nanomaterial being made of single layer of carbon atom, has excellent machinery, electronics and optical property.In visible light
Wave band, graphene all have very high sensitivity to the refractive index fluctuation of any scale of surrounding, show strong polarization according to
Rely absorption characteristic, i.e., the absorption intensity to P-polarized light is much larger than to the absorption intensity of the S polarized light in incident light, it is therefore, incident
S polarized light in light can be totally reflected on the surface of graphene.
By taking cell sample piece as an example, such as colon epidermal cell sample strip, due in cell sample piece cancerous tumor cell with
Normal cell form, size and in terms of it is all different, cause cancerous tumor cell and normal cell in the refractive index of cell membrane
There are larger differences for aspect.Therefore, cellular layer to be detected is attached on graphene-based bottom, is prepared into sample strip 202, the sample
Product piece 202 is under the scanning of detection light, this refractive index sensitivity characteristic based on graphene, and graphene is inclined to the S in detection light
The absorption intensity of vibration light and P-polarized light shows different non-linear changes with the variation of the cellular refractive index at different points of irradiation
Change, can be used for detecting in cell sample piece with the presence or absence of cancer cell.
In the utility model embodiment, scanning is attached with after detecting light and passing through 201 tightly focused of high-NA objective
The graphene-based bottom of cell to be measured, if cellular layer at scanning element there are the variation of refractive index, detect the S polarized light in light can be
The surface at graphene-based bottom is totally reflected, therefore in the experiment optical signal formed at scanning element, the intensity of S polarized light increases
Add, the remitted its fury of P-polarized light, so that carrying the cellular refractive index information at scanning element in experiment optical signal.It is subsequent logical
It crosses photodetector 301 and collects the experiment optical signal, and obtain corresponding electric signal after carrying out photoelectric conversion, optical signal will be tested
In the intensity signal of S polarized light record as electronic signals, the electric signal is then filtered out by lock-in amplifier 302
In noise, improve signal-to-noise ratio after be output in computer control system 303, computer system using MATLAB program to telecommunications
The intensity signal of S polarized light in number carries out simulation based on digital processing, and the intensity signal based on the S polarized light pre-saved with
The corresponding relationship of the refractive index information of sample to be tested can obtain corresponding refractive index information, and the refractive index got is sensitive
Degree is very high, can qualitatively and quantitatively be analyzed with refractive index.
Further, detection light generating device 100 further includes the first reflecting mirror 110 and the second reflecting mirror 111.Such as Fig. 3 institute
Show, the first reflecting mirror 110 is set between spatial light modulator 103 and the polarizer 104, and the second reflecting mirror 111 is set to spiral
Between phase-plate 108 and high-NA objective 201.
First reflecting mirror 110, for reflecting the annular beam projected from spatial light modulator, so that ring light
Beam is incident to the polarizer 104 according to presetting angle.
Second reflecting mirror 111, for reflecting the detection light projected from spiral phase plate 108, so that detection light
High-NA objective 201 is incident to according to presetting angle.
In the utility model embodiment, detects in light generating device 100 and modulated using the optical system on monochromatic light road
Detection light is generated, device is adjusted by the way that beam direction is arranged between certain optical devices in a device, suitably changes the monochromatic light
The direction of beam propagation of road is not limited to each optical device on linear light path, the light beam to improve the flexibility of device
Direction adjustment device can be not limited to reflecting mirror.It is understood that in practical applications, beam direction adjusts the reflection in device
The quantity of mirror and position are also not necessarily limited to distribution scheme provided by the present embodiment, can also be in detection light generating device 100
Other optical devices, as reflecting mirror is arranged in the optical path between the polarizer 104 and concavees lens, for changing the propagation of linearly polarized light
Direction.
Further, refractive index micrometering system further includes optical path adjustment device and sensing imaging device.
Optical path adjustment device includes the first beam splitter 401 and the second beam splitter 402.In practical applications, detection light generates
The first beam splitter 401, scanning probe device 200 and signal acquisition and place are provided between device 100 and scanning probe device 200
The second beam splitter 402 is provided between reason device 300.
Wherein, the first beam splitter 401 for receiving detection light, and detects after light passes through the first beam splitter 401 and enters high number
It is worth in aperture objective 201.The experiment optical signal that first beam splitter 401 is also used to project from high-NA objective 201 is anti-
It is incident upon the second beam splitter 402.
Second beam splitter 402, the experiment optical signal beam splitting for will receive are optical signal transmissive and reflected light signal.And
And the acquisition of optical signal transmissive entering signal and processing unit 300, reflected light signal enter sensing imaging device.Alternatively, transmitted light
Signal enters sensing imaging device, the acquisition of reflected light signal entering signal and processing unit 300.
Imaging device is sensed, for being imaged according to the optical signal transmissive or reflected light signal that receive.
In practical applications, the surface of optical glass is plated into one or more layers film, when light beam projects coated glass
After upper, it is divided into two beams or more, this coated glass is just called beam splitter.In the present embodiment, reflecting mirror and beam splitting
The collocation of mirror uses, and the vertical transformation of beam path may be implemented.Beam splitter has transmission effect and reflex, can will be incident
Light beam is divided into the two-beam with certain beam intensity ratio.
Wherein, the first beam splitter 401 is mounted between the first reflecting mirror 110 and high-NA objective 201, and detection light exists
It is divided into two beams in first beam splitter 401, it is a branch of to enter in high-NA objective 201, for passing through high-NA objective
Sample strip 202 is scanned after 201 focusing, another beam passes through the second beam splitter 402 and enters after focusing by the first convex lens 403
In Signal acquiring and processing device 300, reference optical signal can be used as.Also, the experiment generated when detecting optical scanning sample strip 202
Optical signal is sent into the first beam splitter 401 along optical path after the collection of high-NA objective 201, and in the anti-of the first beam splitter 401
The effect of penetrating is lower to enter the second beam splitter 402, then is split by the second beam splitter 402.
Further, sensing imaging device includes optical filter 501, the second convex lens 502 and charge coupling device ccd image
Sensor 503.
Optical signal transmissive or reflected light signal successively pass through optical filter 501 and filter out effect, second to the light of specific wavelength
It after the diffusion of convex lens 502, is incident upon on ccd image sensor 503, the ccd image sensor 503 is to be measured for rendering
The bright field image of sample.
In the present embodiment, optical filter 501 is long pass filter, for filtering out swashing for the specific wavelength in experiment optical signal
Optical signal is all larger than the wavelength of the laser signal of the offer of laser 101 across the wavelength of the optical signal of the optical filter 501.The light
On the corresponding sense channel that signal projects ccd image sensor 503 after the focusing of the second convex lens 502, obtain to test sample
The bright field image of product.Ccd image sensor 503 carries out light signal collection by the way of time delay integration, and suitable
Under diaphragm is adjusted, the bright field image of sample is clear, good at image contrast, ensure that the matter of 503 acquired image of ccd image sensor
Amount, for positioning sample to be detected.If the micro-image of cell and each can be obtained simultaneously using cell as observation sample
The spectral signal of pixel, the phase and amplitude information of cell can be obtained through spectrum analysis, to extract the effective nanometer of cell
Architectural characteristic realizes that high-precision is imaged.
In the above-described embodiments, it all emphasizes particularly on different fields to the description of each embodiment, there is no the portion being described in detail in some embodiment
Point, it may refer to the associated description of other embodiments.
The above are to a kind of description of refractive index micrometering system provided by the embodiment of the utility model, for this field
Technical staff have change in specific embodiments and applications based on the idea of the embodiment of the present invention
Place, to sum up, the content of the present specification should not be construed as a limitation of the present invention.
Claims (10)
1. a kind of refractive index micrometering system characterized by comprising
Detect light generating device, scanning probe device and Signal acquiring and processing device;
The detection light for providing the detection light with tightly focused characteristic, and is incident to institute by the detection light generating device
State scanning probe device;
The scanning probe device focuses on the detection light in sample strip, for being scanned the sample strip to generate
Optical signal is tested, and the experiment optical signal is incident to the Signal acquiring and processing device, is wrapped in the experiment optical signal
Refractive index information containing the sample strip;
The Signal acquiring and processing device includes for acquiring the experiment optical signal, and to the experiment optical signal
After photoelectric conversion, denoising and the processing of information extraction, the refractive index information of the sample strip is obtained.
2. refractive index micrometering system according to claim 1, which is characterized in that the Signal acquiring and processing device
Including photodetector, lock-in amplifier and computer control system;
The photodetector is converted to corresponding telecommunications for acquiring the experiment optical signal, and by the experiment optical signal
Output is to the lock-in amplifier after number;
The lock-in amplifier, for receiving the electric signal, and to defeated after the electric signal progress denoising received
Out to the computer control system;
The computer control system for receiving the electric signal after denoising, and extracts institute from the electric signal after the denoising
State the refractive index information of sample strip.
3. refractive index micrometering system according to claim 1, which is characterized in that the detection light generating device includes
Laser, chopper, spatial light modulator, the polarizer, concavees lens group, half wave plate, the vortex set gradually in optical path
Wave plate and spiral phase plate;
The laser, for providing the continuous laser of preset wavelength;
The chopper, for the continuous laser of the preset wavelength to be modulated into the laser signal with fixed frequency;
The spatial light modulator, for the laser signal with fixed frequency to be modulated into annular beam;
The polarizer, for the annular beam to be modulated into linearly polarized light;
The concavees lens group, for being expanded to the linearly polarized light;
The half wave plate, for changing the polarization direction of the linearly polarized light after expanding;
The vortex wave plate obtains angularly polarized light for carrying out phase regulation to the linearly polarized light behind change polarization direction;
The spiral phase plate obtains the angular polarization that topological charge values are+1 for increasing the topological charge of the angularly polarized light
Light, using the angularly polarized light that the topological charge values are+1 as detection light.
4. refractive index micrometering system according to claim 3, which is characterized in that the scanning probe device includes height
NA objective;
The numerical aperture of the high-NA objective is not less than 1.49;
The high-NA objective is focused into point light source for receiving the detection light, and by the detection light received
After scan the sample strip;It is also used to collect in scanning process, the point light source is radiated at the experiment generated in the sample strip
Optical signal.
5. refractive index micrometering system according to claim 4, which is characterized in that the scanning probe device further includes
Objective table;
The sample strip is placed on the objective table;
The objective table is connect with computer control system, for controlling the movement of the objective table, to realize the point light source
To the sample strip point by point scanning.
6. refractive index micrometering system according to claim 2, which is characterized in that the sample strip includes graphene-based
Bottom and the sample to be tested being attached on the graphene-based bottom;
The detection light reflects on the surface at the graphene-based bottom and sample to be tested, generates experiment optical signal, and be based on
The polarization absorption characteristic of graphene, the refractive index difference of the sample to be tested lead to the S polarized light in the experiment optical signal
Intensity changes.
7. refractive index micrometering system according to claim 6, which is characterized in that the number of the computer control system
It is used to acquire and store the intensity signal of the S polarized light in the experiment optical signal according to capture card;
The corresponding pass of the intensity signal of S polarized light and the refractive index information of sample to be tested is preserved in the computer control system
System.
8. refractive index micrometering system according to claim 4, which is characterized in that the detection light generating device also wraps
Include the first reflecting mirror and the second reflecting mirror;
First reflecting mirror, for reflecting the annular beam projected from the spatial light modulator, so that described
Annular beam is incident to the polarizer according to presetting angle;
Second reflecting mirror, for reflecting the detection light projected from the spiral phase plate, so that the detection
Light is incident to the high-NA objective according to presetting angle.
9. refractive index micrometering system according to claim 4, which is characterized in that the refractive index micrometering system
It further include optical path adjustment device and sensing imaging device;
The optical path adjustment device includes the first beam splitter and the second beam splitter;
The detection light enters the high-NA objective after passing through first beam splitter;
First beam splitter, the experiment optical signal for being also used to project from the high-NA objective are reflected into described
Two beam splitters;
Second beam splitter, for the experiment optical signal received to be divided into optical signal transmissive and reflected light signal;
The optical signal transmissive enters in the Signal acquiring and processing device, and the reflected light signal is imaged into the sensing
Device;
Alternatively, the optical signal transmissive enters in the sensing imaging device, the reflected light signal enters the signal acquisition
With processing unit;
The sensing imaging device, for being imaged according to the optical signal transmissive or reflected light signal.
10. refractive index micrometering system according to claim 9, which is characterized in that the sensing imaging device includes
Optical filter, convex lens and charge coupling device ccd image sensor;
The optical signal transmissive or reflected light signal successively filter out effect, described to the light of specific wavelength by the optical filter
It after the focussing force of convex lens, is incident upon on the ccd image sensor, the ccd image sensor is for rendering to test sample
The bright field image of product.
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CN109142273A (en) * | 2018-09-07 | 2019-01-04 | 深圳大学 | A kind of refractive index micrometering system |
CN111533083A (en) * | 2020-05-08 | 2020-08-14 | 中北大学 | Miniature molecular optical tweezers based on graphene |
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Cited By (3)
Publication number | Priority date | Publication date | Assignee | Title |
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CN109142273A (en) * | 2018-09-07 | 2019-01-04 | 深圳大学 | A kind of refractive index micrometering system |
CN111533083A (en) * | 2020-05-08 | 2020-08-14 | 中北大学 | Miniature molecular optical tweezers based on graphene |
CN111533083B (en) * | 2020-05-08 | 2023-09-05 | 中北大学 | Miniature molecular optical tweezers based on graphene |
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