CN202305396U - Near-field Tera Hertz (THz) time-domain spectrum testing device - Google Patents

Abstract

The utility model relates to a near-field Tera Hertz (THz) time-domain spectrum testing device. A light pulse output by a femtosecond laser light source passes through a semiwave polarizer, and then is divided by an optical beam divider into a pump light and a detecting light; the light path of the device comprises a pump light path and a detecting light path; the detecting light passes through an optical delay line and the detecting light path and then is coincided with the pump light path at the electro-optical crystal position; an electro-optical crystal and a lens are arranged at the position corresponding to the placing position of a test specimen; the optical signal, which is from the test specimen and collected by the electro-optical crystal, passes through the lens, and is conveyed to a wave plate and a Wollaston prism by a Wollaston polarized light beam divider so as to be divided into a P light and an S light; the two lights are conveyed to a photoelectric detector, and the photoelectric detector carries out photoelectric conversion so as to output an electrical signal; the output electrical signal is amplified by a lock-in amplifier; and the synchronization frequency signal of the lock-in amplifier is from the pump light path or an optical chopper in the detecting light path.

Description

Near field Terahertz THz time-domain spectroscopy proving installation

Technical field

The utility model relates to a kind of near field Terahertz THz time-domain spectroscopy characterizing method and proving installation thereof that is applied to quasi-one dimensional nanostructure semiconductor or metal material.

Background technology

Generally; What THz-TDS system of most terahertz time-domain spectroscopy system all adopted is at THz transmission of far-field measurement Terahertz or reflected signal, and this mainly is because the pattern (block of material, polymeric material etc.) of specimen itself and existing Terahertz THz detection light path have limited the near field mode.Under the far field condition, owing to there is diffraction phenomena, the spatial resolution of terahertz time-domain spectroscopy THz-TDS and THz imaging system is by big limitations.In nanometer electronic device research; People need the exciton of understanding quasi-one dimensional nanostructure semiconductor or metal material badly and generate and process such as separate, free charge transports, captures, and then whether the pattern, defective, doping, annealing etc. of understanding material help improving its photovoltaic applications attribute.

In the past several years; People attempt utilizing aperture (Aperture) technology to realize the Terahertz THz signal measurement under the mode of near field, but along with diaphragm diameter dwindles, Terahertz THz light signal energy also sharply reduces; Flooded by background noise probably, be unfavorable for improving the signal to noise ratio (S/N ratio) of system.Recent years; (Scanning Near-field Optical Microscopy SNOM) develops and the micro-THz-SNOM method of Terahertz near-field scan many researcher's reference scan type summarization of Near-Field Optical Microscopy, and resolution is brought up to the half the of Terahertz THz optical wavelength even 1/10th; Effect is obvious; But this method signal to noise ratio (S/N ratio) is low, and the system architecture complexity is big, and cost is very expensive.

Summary of the invention

Technical matters: the purpose of the utility model is for a kind of near field Terahertz THz time-domain spectroscopy characterizing method and relevant proving installation to quasi-one dimensional nanostructure semiconductor or metal material is provided.

Technical scheme: it is very fast that contactless, the low-energy terahertz time-domain spectroscopy THz-TDS of system method is applied to semiconductor material research development recent years; According to material effects after the amplitude and the phase change of THz signal, can obtain information such as material complex permittivity, photoconductivity, carrier mobility and relaxation time constant.The utility model is devoted to realize a kind of THz near field transmission/emission time-domain spectroscopy characterization technique of complementation: 1, through amplitude and phase change behind measurement THz light and the sample effect, obtain the refractive index n and the extinction coefficient k information of sample; 2, accurate one-dimentional structure semiconductor or the metal material with nanoscale is placed on the pumping light path; Utilize femto-second laser pulse (800nm; 70fs～120fs 75MHz) shines and makes it become Terahertz THz emissive source, through the THz optical signal magnitude of measuring samples self emission.

A kind of near field Terahertz THz time-domain spectroscopy proving installation comprises femtosecond laser light source, the half-wave polarizer, optical beam-splitter, optical chopper, solid Terahertz emissive source, optical delay, wave plate, electro-optic crystal, Wollaston polarising beam splitter, photodetector and lock-in amplifier;

The femtosecond laser light source output optical pulse behind the half-wave polarizer, is divided into pump light and is detected light by optical beam-splitter; The light path of this device comprises the pumping light path and detects light path; Detecting light overlaps at the electro-optic crystal place with the pumping light path through optical delay line and detection light path;

The corresponding pumping light path of pump light on the pumping light path, is provided with fixing optical chopper, detachable solid Terahertz emissive source and specimen placement location along the direction of illumination of light successively; Said optical chopper output is used for the synchronous frequency signal of lock-in amplifier;

Detect the corresponding light path that detects of light; Detecting on the light path, be provided with optical delay, Wollaston polarising beam splitter, wave plate and Wollaston prism;

With specimen placement location corresponding position electro-optic crystal and lens are set; Electro-optic crystal gather from the specimen light signal behind lens; Deliver to wave plate and Wollaston prism through the Wollaston polarising beam splitter again; Be divided into P light and S light, these two lighies velocity are sent into photodetector, and the electric signal that photodetector carries out exporting after the opto-electronic conversion is amplified by lock-in amplifier; The synchronous frequency signal of lock-in amplifier is from the pumping light path or from the optical chopper that detects in the light path.

Said electro-optic crystal is a zinc telluridse ZnTe electro-optic crystal as Terahertz THz detector; The ultimate range on electro-optic crystal and sample surface is less than 1.0cm;

Zinc telluridse ZnTe electro-optic crystal is docile and obedient preface towards the surface of a side of specimen and is prepared silicon dioxide SiO ₂Film and germanium Ge film adopt the mode of electron beam evaporation to prepare.

Said silicon dioxide SiO ₂The thickness of film is 133nm ± 10%; Germanium Ge film thickness is 300nm ± 10%.

Said solid Terahertz emissive source is passive nonlinear optics rectification crystal or active photoconductive antenna; Said wave plate is λ/2 or λ/4 wave plates; Said photodetector is the difference photodetector.

A kind of near field terahertz time-domain spectroscopy method of testing of using said apparatus is characterized in that comprising two kinds of test patterns: Terahertz THz passes through/reflection spectrometry and emission spectrum method:

First test pattern: pass through/the reflection spectrometry is for using the sample of Terahertz THz optical signal radiation nanostructured, pass through through measuring Terahertz THz through specimen/amplitude and the phase information of reflected signal, carry out spectral characterization;

Second test pattern: the emission spectrum rule is to utilize the specimen of near infrared femto-second laser pulse direct radiation nanostructured, motivates the Terahertz THz light signal with certain amplitude and phase information, in order to as spectral analysis;

The emission spectrometry is realized through in the pumping light path, removing or adding the solid Terahertz emissive source of adjusting with the switching of passing through/reflecting spectrometry, wherein, solid Terahertz emissive source is set for passing through/the reflection spectrometry in the pumping light path;

This method is to carry out the Terahertz THz time-domain spectroscopy THz-TDS sign under the mode of near field to the accurate one dimension semiconductor of nanoscale or metal Nano structure.

The principle of present technique scheme is explained as follows:

The device that the utility model proposes adopts pumping-detection optical system, mainly comprises femtosecond laser light source, beam splitter, optical chopper, optics time delay guide rail, wave plate (λ/2 and λ/4), solid Terahertz emissive source (nonlinear optical crystal or photoconductive antenna), electro-optic crystal, Wollaston polarising beam splitter, difference photodetector and lock-in amplifier.The light path of device is divided into the pumping light path and detects light path; The femtosecond laser light source output optical pulse; Behind the half-wave polarizer, be divided into pump light and detect light by optical beam-splitter, the accurate one-dimentional structure material that pump light is used to encourage solid Terahertz emissive source or nanoscale is to excite the generation of Terahertz THz light; Behind optical delay, be overlapped in electro-optic crystal and detect light, accomplish the collection of Terahertz THz light amplitude and phase information with Terahertz THz light wave; Be divided into P light beam and S light beam through the optical signals Wollaston of electro-optic crystal collection polarising beam splitter, and send into the difference photodetector, the electric signal of exporting after the opto-electronic conversion carries out necessary amplification by lock-in amplifier; The synchronous frequency signal that lock has amplified mutually is from the pumping light path or detect the optical chopper in the light path.

Because the quasi-one dimensional nanostructure material has the nanoscale characteristics; To be placed on the accurate one-dimentional structure material sample of nanoscale near surface as the zinc telluridse ZnTe electro-optic crystal of Terahertz THz detector in the scheme of the utility model; Ultimate range is less than 1.0cm, and zinc telluridse ZnTe electro-optic crystal is docile and obedient preface towards a side surface of specimen and is prepared silicon dioxide SiO ₂Film, the about 133nm of thickness, in order to farthest reducing the laser-transmitting energy of pumping light path, and germanium Ge film, thickness is about 300nm, in order to improve the absorptivity of THz lightwave signal.

Compared to the THz-TDS of terahertz time-domain spectroscopy system of in the past far field pattern, the utility model is a kind of near field Terahertz THz time-domain spectroscopy system to nanoscale semiconductor or metal material.

Beneficial effect: the present technique scheme can be used for the spectral analysis of nanoscale metal or semiconductor material, has improved spatial resolution effectively.In addition, the time-domain spectroscopy system in the utility model can realize the switching between transmission/reflective-mode and the emission mode, helps the complementation on the measuring method, has improved flexibility ratio and the accuracy measured.

Description of drawings:

Fig. 1 is the Terahertz near field time domain emission spectrum system diagram that is directed against the accurate one-dimensional material of nanoscale in the utility model.

Fig. 2 is the Terahertz near field time domain transmission/reflectance spectrum system diagram that is directed against the accurate one-dimensional material of nanoscale in the utility model.

Fig. 3 is Terahertz crystal detection and its surface optics film design figure in the utility model.

Label among the figure: 1-silicon dioxide SiO ₂Film, 2-germanium Ge film, 3-Terahertz THz photodetection crystal.

Embodiment

A kind of near field Terahertz THz time-domain spectroscopy proving installation comprises femtosecond laser light source, the half-wave polarizer, optical beam-splitter, optical chopper, solid Terahertz emissive source, optical delay, wave plate, electro-optic crystal, Wollaston polarising beam splitter, photodetector and lock-in amplifier;

The femtosecond laser light source output optical pulse behind the half-wave polarizer, is divided into pump light and is detected light by optical beam-splitter; The light path of this device comprises the pumping light path and detects light path; Detecting light overlaps at the electro-optic crystal place with the pumping light path through optical delay line and detection light path;

The corresponding pumping light path of pump light on the pumping light path, is provided with fixing optical chopper, detachable solid Terahertz emissive source and specimen placement location along the direction of illumination of light successively; Said optical chopper output is used for the synchronous frequency signal of lock-in amplifier;

Detect the corresponding light path that detects of light; Detecting on the light path, be provided with optical delay, Wollaston polarising beam splitter, wave plate and Wollaston prism;

With specimen placement location corresponding position electro-optic crystal and lens are set; Electro-optic crystal gather from the specimen light signal behind lens; Deliver to wave plate and Wollaston prism through the Wollaston polarising beam splitter again; Be divided into P light and S light, these two lighies velocity are sent into photodetector, and the electric signal that photodetector carries out exporting after the opto-electronic conversion is amplified by lock-in amplifier; The synchronous frequency signal of lock-in amplifier is from the pumping light path or from the optical chopper that detects in the light path.

Said electro-optic crystal is a zinc telluridse ZnTe electro-optic crystal as Terahertz THz detector; The ultimate range on electro-optic crystal and sample surface is less than 1.0cm;

Zinc telluridse ZnTe electro-optic crystal is docile and obedient preface towards the surface of a side of specimen and is prepared silicon dioxide SiO ₂Film and germanium Ge film adopt the mode of electron beam evaporation to prepare.

Said silicon dioxide SiO ₂The thickness of film is 133nm ± 10%; Germanium Ge film thickness is 300nm ± 10%.

Said solid Terahertz emissive source is passive nonlinear optics rectification crystal or active photoconductive antenna; Said wave plate is λ/2 or λ/4 wave plates; Said photodetector is the difference photodetector.

A kind of near field terahertz time-domain spectroscopy method of testing of using said apparatus is characterized in that comprising two kinds of test patterns: Terahertz THz passes through/reflection spectrometry and emission spectrum method:

First test pattern: pass through/the reflection spectrometry is for using the sample of Terahertz THz optical signal radiation nanostructured, pass through through measuring Terahertz THz through specimen/amplitude and the phase information of reflected signal, carry out spectral characterization;

Second test pattern: the emission spectrum rule is to utilize the specimen of near infrared femto-second laser pulse direct radiation nanostructured, motivates the Terahertz THz light signal with certain amplitude and phase information, in order to as spectral analysis;

The emission spectrometry is realized through in the pumping light path, removing or adding the solid Terahertz emissive source of adjusting with the switching of passing through/reflecting spectrometry, wherein, solid Terahertz emissive source is set for passing through/the reflection spectrometry in the pumping light path;

This method is to carry out the Terahertz THz time-domain spectroscopy THz-TDS sign under the mode of near field to the accurate one dimension semiconductor of nanoscale or metal Nano structure.

Below in conjunction with accompanying drawing and embodiment the present technique scheme is described further:

The present technique scheme is a kind of near field terahertz time-domain spectroscopy system to the accurate one-dimentional structure material of nanoscale, can be used alternatingly Terahertz and pass through/reflectance spectrum and Terahertz emission spectrum.

The utility model at first is divided into the near infrared femtosecond pulse light beam of femtosecond laser light source radiation the pumping light path and is detected light path by optical beam-splitter; Pump light encourages the specimen of the accurate one-dimentional structure of solid Terahertz emissive source or nanoscale after the optical chopper modulation, to produce the required terahertz wave signal of analysis of spectrum; Detect light and overlap at Terahertz crystal detection place with the pumping light path, and realize sampling terahertz signal through optical delay line and necessary delivery optics; Through detecting the terahertz signal process quarter-wave plate and the Wollaston prism of gloss appearance; Be divided into P light and S light; Send into the input end of difference photodiode respectively; Its small-signal output terminal is exported differential signal and is handled (amplifying and analog to digital conversion) by the lockin signal amplifier, and the synchronous frequency signal of lock-in amplifier is from optical chopper; Signal data after the processing is sent to that computing machine is for further processing and operational analysis.

In the utility model; The switching of transmission/reflectance spectrum and emission spectrum mode is employed in to remove in the pumping light path or add solid Terahertz emissive source module and realizes: remove solid Terahertz emissive source module; Specimen with the accurate one-dimentional structure of pumping light path direct radiation nanoscale; Motivate THz wave by sample self, test pattern is the emission spectrum pattern; Add and adjust ground solid Terahertz emissive source; Produce terahertz light by pump optical radiation and stimulated emission source; And carry out necessary focusing, and the specimen of shining the accurate one-dimentional structure of nanoscale subsequently by terahertz light, test pattern is transmission/reflectance spectrum pattern.

The utility model is a kind of near field terahertz light spectra system; Wherein the sample that the Terahertz crystal detection is approached the accurate one-dimentional structure of nanoscale is adopted in the detection of terahertz signal; The ultimate range of both apart is not more than 1cm, prepares silicon dioxide SiO at the Terahertz crystal detection successively near a side surface of sample ₂Film, the about 133nm of thickness, in order to farthest reducing the laser-transmitting energy of pumping light path, and germanium Ge film, thickness is about 300nm, in order to improve the absorptivity of THz lightwave signal.

Embodiment 1

The Terahertz THz near field time domain spectrum (transmission mode) of the accurate one-dimentional structure zinc paste of nanoscale ZnO material

The zinc oxide sample that at first will choose is attached on the optical bench, and puts it in the Terahertz near field time domain spectroscopic system; Open the preceding diaphragm of femtosecond laser light source output window; The output femto-second laser pulse; Utilize optical beam-splitter that it is divided into pump light and detects light; Pump light excitation Terahertz photoelectricity lead antenna through the optical chopper modulation gives off terahertz signal, projects the surface of the accurate one-dimentional structure zinc oxide sample of nanometer after the line focus; The surface prepared successively has the Terahertz crystal detection of silica membrane and germanium film zinc telluridse ZnTe to be placed on the light path of Terahertz THz light transmission, is 0.4cm apart from the zinc oxide sample distance; Survey light and behind optical delay, overlap at Terahertz crystal detection zinc telluridse ZnTe place, accomplish sampling with the Terahertz THz light path of process zinc oxide sample; Terahertz THz signal after the sampling is sent into the input section of difference photodiode through quarter-wave plate and Wollaston prism, accomplishes opto-electronic conversion, and the small-signal of output is by amplifying and analog to digital conversion with the synchronous lock-in amplifier of optical chopper; Computing machine receives and stores the discrete data of the terahertz signal after lock-in amplifier is handled through data-interface, and can realize Fast Fourier Transform (FFT), transfers time-domain signal to frequency-region signal.

Utilize above-mentioned frequency domain and time domain terahertz signal,, can carry out the analysis and the comparison of correspondence with photoelectric properties the material properties of the zinc oxide sample of the accurate one-dimentional structure of nanoscale to be tested according to corresponding physical model or principle.

Embodiment 2

The Terahertz THz near field time domain spectrum (emission mode) of the accurate one-dimentional structure zinc paste of nanoscale ZnO material

The zinc oxide sample that at first will choose is attached on the optical bench, and puts it in the Terahertz near field time domain spectroscopic system; Open the preceding diaphragm of femtosecond laser light source output window; The output femto-second laser pulse; Utilize optical beam-splitter that it is divided into pump light and detects light; Project the surface of the accurate one-dimentional structure zinc oxide sample of nanometer after the pump light line focus through the optical chopper modulation, the excited nano zinc oxide sample gives off terahertz signal; The surface prepared successively has the Terahertz crystal detection of silica membrane and germanium film zinc telluridse ZnTe to be placed on the light path of Terahertz THz light transmission, is 0.4cm apart from the zinc oxide sample distance; Survey light and behind optical delay, overlap at Terahertz crystal detection zinc telluridse ZnTe place, accomplish sampling with the Terahertz THz light path of process zinc oxide sample; Terahertz THz signal after the sampling is sent into the input section of difference photodiode through quarter-wave plate and Wollaston prism, accomplishes opto-electronic conversion, and the small-signal of output is by amplifying and analog to digital conversion with the synchronous lock-in amplifier of optical chopper; Computing machine receives and stores the discrete data of the terahertz signal after lock-in amplifier is handled through data-interface, and can realize Fast Fourier Transform (FFT), transfers time-domain signal to frequency-region signal.

Utilize above-mentioned frequency domain and time domain terahertz signal,, can carry out the analysis and the comparison of correspondence with photoelectric properties the material properties of the zinc oxide sample of the accurate one-dimentional structure of nanoscale to be tested according to corresponding physical model or principle.

Claims (4)

1. a near field Terahertz THz time-domain spectroscopy proving installation is characterized in that comprising femtosecond laser light source, the half-wave polarizer, optical beam-splitter, optical chopper, solid Terahertz emissive source, optical delay, wave plate, electro-optic crystal, Wollaston polarising beam splitter, photodetector and lock-in amplifier;

The femtosecond laser light source output optical pulse behind the half-wave polarizer, is divided into pump light and is detected light by optical beam-splitter; The light path of this device comprises the pumping light path and detects light path; Detecting light overlaps at the electro-optic crystal place with the pumping light path through optical delay line and detection light path;

The corresponding pumping light path of pump light on the pumping light path, is provided with fixing optical chopper, detachable solid Terahertz emissive source and specimen placement location along the direction of illumination of light successively; Said optical chopper output is used for the synchronous frequency signal of lock-in amplifier;

Detect the corresponding light path that detects of light; Detecting on the light path, be provided with optical delay, Wollaston polarising beam splitter, wave plate and Wollaston prism;

With specimen placement location corresponding position electro-optic crystal and lens are set; Electro-optic crystal gather from the specimen light signal behind lens; Deliver to wave plate and Wollaston prism through the Wollaston polarising beam splitter again; Be divided into P light and S light, these two lighies velocity are sent into photodetector, and the electric signal that photodetector carries out exporting after the opto-electronic conversion is amplified by lock-in amplifier; The synchronous frequency signal of lock-in amplifier is from the pumping light path or from the optical chopper that detects in the light path.

2. device according to claim 1 is characterized in that said electro-optic crystal as Terahertz THz detector, is zinc telluridse ZnTe electro-optic crystal; The ultimate range on electro-optic crystal and sample surface is less than 1.0cm;

Zinc telluridse ZnTe electro-optic crystal is docile and obedient preface towards the surface of a side of specimen and is prepared silicon dioxide SiO ₂Film and germanium Ge film adopt the mode of electron beam evaporation to prepare.

3. device according to claim 2 is characterized in that said silicon dioxide SiO ₂The thickness of film is 133nm ± 10%; Germanium Ge film thickness is 300nm ± 10%.

4. device according to claim 2 is characterized in that said solid Terahertz emissive source is passive nonlinear optics rectification crystal or active photoconductive antenna; Said wave plate is λ/2 or λ/4 wave plates; Said photodetector is the difference photodetector.

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