JP2009080007A - Time-resolved spectroscopy system, time-resolved spectroscopy method and terahertz wave generation system - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a time-resolved spectroscopy system, etc. less sensitive to disturbance and capable of adjusting delay time. <P>SOLUTION: The time-resolved spectroscopy system (1) includes a light pulse generator (3) to input light from a continuous light source (2), a drive signal generator (4) to drive the light pulse generator (3), and a light detector (5) to detect light from a measured object, in which spectroscopic analysis is performed by obtaining detection light using a light pulse generating at the light pulse generator (3), irradiating the measured object with the detection light, and detecting transmitting light or reflected light from the measured object using the light detector (5). <P>COPYRIGHT: (C)2009,JPO&INPIT

Description

  The present invention relates to a time-resolved spectroscopy system and the like. More specifically, the present invention relates to a time-resolved spectroscopic system, a terahertz wave generating system, and the like including an optical pulse generator that can be modulated. The present invention also relates to a system for generating / detecting electromagnetic waves in a terahertz region (100 GHz to 10 THz) using an ultrashort light pulse, a spectroscopic system, or the like.

2. Description of the Related Art In the fields of optical communication and physical property research, optical signals that change within a time on the order of femtoseconds ( ^10-15 seconds) to picoseconds ( ^10-12 seconds) are actively used. Such a change in the optical signal can be measured by time-resolved spectroscopic measurement with high time resolution. Therefore, a time-resolved spectroscopic system with high time resolution is desired.

  FIG. 1 is a block diagram illustrating a configuration example of a conventional time-resolved spectrometer. As shown in FIG. 1, a conventional time-resolved spectroscopic device (101) is mechanically driven by a mode-locked laser (102) that is an ultrashort optical pulse laser, a beam splitter (103) that splits the laser light, and the like. A movable mirror (104) and a light intensity modulator (105) are included. Then, the pulse light from one ultrashort optical pulse laser is branched into two or more by a beam splitter. Then, by reflecting one pulsed light with a movable mirror, the arrival time at an arbitrary position with respect to the other light pulse is changed (Non-Patent Document 1). This time-resolved spectroscope has problems such as inaccurate timing control due to the mechanical accuracy of the movable stage, a long measurement time, or all branched pulsed light having the same wavelength.

FIG. 2 is a block diagram showing a configuration example of a conventional time-resolved spectroscopic device, which is different from that shown in FIG. As shown in FIG. 2, there is a conventional time-resolved spectrometer (111) having two ultrashort optical pulse lasers (112, 113). This time-resolved spectrometer changes the arrival time of an optical pulse at an arbitrary position by precisely controlling the cavity length of one or both ultrashort optical pulse lasers and operating them at different repetition rates.
(Non-patent document 2). This time-resolved spectrometer has a complicated cavity length control mechanism for obtaining different repetition frequencies, and each optical pulse laser has independent timing jitter, and has problems in energy resolution, accuracy, and S / N ratio. There was a problem that the mechanism to control it was complicated.

  In addition, these conventional time-resolved spectrometers require precise control of the optical system, so they are vulnerable to disturbances due to environmental changes (for example, temperature changes and vibrations), and the repetition frequency is almost fixed. And the drawbacks were large equipment.

An electromagnetic wave region (a terahertz wave region, for example, a frequency region of about 100 GHz to 10 THz) around a frequency of 1 THz (terahertz) is a frequency region located at the boundary between light waves and radio waves. In this frequency range, development of light sources and detectors is relatively delayed, and there are many undeveloped parts in both technical and application aspects. Therefore, development of an effective terahertz wave generation system is desired.
Ultra fast Spectroscopy of Semiconductors and Semiconductor Nanostructures, section 1.3 Applied Physics Letters, vol. 87, p061101 (2005)

  An object of the present invention is to provide a time-resolved spectroscopic system and a spectroscopic method that are not easily affected by disturbance.

  An object of the present invention is to provide a time-resolved spectroscopic system and a spectroscopic method capable of adjusting a delay time while maintaining accuracy.

  An object of the present invention is to provide an effective terahertz wave generation system.

  The present invention is basically based on the knowledge that a time-resolved spectroscopic system having a preferable resolution can be provided by using an optical pulse generator having a variable repetition frequency as a light source. In particular, the present invention is based on the knowledge that a time-resolved spectroscopic system that is not easily affected by disturbance can be provided by using an optical pulse generator that does not have an optical resonator.

  A first aspect of the present invention is a time-resolved spectroscopic system (1), which drives an optical pulse generator (3) to which light from a continuous light source (2) is input, and the optical pulse generator (3). A drive signal generator (4) for detecting light and a light detector (5) for detecting light from the object to be measured, and using the light pulse generated by the light pulse generator (3) A time-resolved spectroscopic system that obtains detection light, irradiates the measurement object with the detection light, and detects the transmitted light or reflected light from the measurement object by the photodetector (5). About.

  By using the optical pulse generator (3) having the drive signal generator (4) in this way, a time-resolved spectroscopic system that does not use a resonator or the like can be provided. This makes it possible to provide a time-resolved spectroscopy system that is less susceptible to disturbances. Furthermore, by controlling the high-frequency signal with the drive signal generator (4), the repetition frequency of the optical pulse can be easily changed and adjusted easily, and the delay time can also be controlled easily. A spectroscopic system can be provided. In particular, a terahertz wave can be generated by adjusting the repetition frequency of an optical pulse from an optical pulse generator to generate an ultrashort pulse, and a time spectroscopy system using the terahertz wave can be provided.

  A preferred embodiment of the present invention further comprises intensity modulation means (7) for modulating the intensity of the continuous light source (2), and converts the continuous wave light intensity-modulated by the intensity modulation means (7) into the optical pulse. The system according to the above, which enters the generator (3), obtains an intensity-modulated light pulse, and performs a spectroscopic analysis using the intensity-modulated light pulse.

  In the past, intensity modulation was performed using physical means such as an optical chopper. However, in this aspect, since the intensity modulation means (7) is provided, an intensity modulation signal can be obtained without physically performing light intensity modulation by shielding light. This makes it possible to provide a time-resolved spectroscopic system that is less susceptible to disturbances.

  Specifically, the continuous light source (2) is a semiconductor laser, and the intensity modulation means (7) is a modulation signal generator for driving the semiconductor laser. System.

  A preferred aspect of the present invention relates to any one of the above systems, further comprising an optical fiber for propagating an optical pulse signal generated from the optical pulse generator. The optical fiber may be used as an optical pulse generator that generates an optical pulse signal. By using an optical fiber, it is possible to irradiate a light pulse from the very vicinity of the object. Furthermore, by using an optical fiber, a light pulse can be emitted from an arbitrary place.

  In a preferred aspect of the present invention, the optical pulse generator (3) includes a plurality of optical pulse generators (3), and each optical pulse generator (3) is driven at a different repetition frequency to perform delay time sweeping. The described system.

  By using a plurality of optical pulse generators (3a, 3b), pump light and probe light can be obtained without using optical elements.

  A preferred embodiment of the present invention includes a plurality of the optical pulse generators (3), and outputs from the optical pulse generator (3) by controlling the frequency of the drive signal of each drive signal generator (4). The system according to any one of the above, wherein the delay time can be controlled by controlling the repetition frequency of the optical pulse to be generated.

  That is, in the time-resolved spectroscopic system as shown in FIG. 1, the delay time is controlled using a movable stage. However, the movable stage has poor time response and cannot be adjusted with high accuracy. In the above aspect, the delay time can be accurately controlled by a simple method of adjusting the drive signal of the optical pulse generator.

  In a preferred aspect of the present invention, the optical pulse generator (3) includes an optical input unit (12), a branch unit (13) where light input to the input unit branches, and the branch unit (13). A first waveguide (14) through which the branched light propagates, a second waveguide (15) through which light different from the above branched from the branch section (13) propagates, and the first waveguide An optical signal output from the second waveguide, and an optical signal output unit from which the optical signal combined by the optical output unit is output. The drive signal generator (4) drives a first drive signal (19) for driving the first waveguide and the second waveguide. A drive signal system (21) for obtaining a second drive signal (20), and a bias signal (22, 23) for obtaining a bias signal (22, 23) applied to the first waveguide and the second waveguide. Scan signal system (24); a system according to the any one having a.

  By using the above-described optical pulse generator and drive signal generator, it is possible to obtain an optical pulse that is extremely homogeneous and extremely responsive. As a result, it is possible to provide an extremely accurate time-resolved spectroscopic system.

In a preferred aspect of the present invention, the drive signal system (21) and the bias signal system (24) include the first drive signal (19), the second drive signal (20), and the bias signal (22, 23). Relates to the system described above, which is driven to satisfy the following formula (I).
ΔA + Δθ = π / 2 (I)
(Where ΔA and Δθ are defined as ΔA≡ (A ₁ −A ₂ ) / 2 and Δθ≡ (θ ₁ −θ ₂ ) / 2, respectively, where A ₁ and A ₂ are the first modulation electrodes, respectively. And the optical phase shift amplitude induced in the second modulation electrode, and θ ₁ and θ ₂ indicate the optical phase shift amount induced in the first waveguide and the second waveguide, respectively)

  As will be described later, by driving to satisfy the above formula (I), two phase modulators to be combined (a phase modulator is constituted by a waveguide and an electrode to which a drive signal is applied) are combined. The optical signals complement each other, and an optical pulse signal with good spectral characteristics can be obtained.

  A second aspect of the present invention is a time-resolved spectroscopic method using a time-resolved spectroscopic system (1), wherein the time-resolved spectroscopic system (1) is a light pulse input by light from a continuous light source (2). A generator (3), a drive signal generator (4) for driving the optical pulse generator (3), and a photodetector (5) for detecting light from the measurement object Then, detection light is obtained using the light pulse generated by the light pulse generator (3), the detection light is irradiated onto the measurement object, and transmitted light or reflected light from the measurement object is used as the light detector. The present invention relates to a time-resolved spectroscopic method in which spectroscopic analysis is performed by detecting.

  In the above method, since the spectroscopic analysis can be performed without using an external resonator or the like, it is possible to provide a spectroscopic method which is not easily affected by disturbance.

  A preferred embodiment of the second aspect of the present invention is a time-resolved spectroscopic method using a time-resolved spectroscopic system (1), and the time-resolved spectroscopic system (1) receives light from a continuous light source (2). A plurality of optical pulse generators (3a, 3b), a drive signal generator (4a, 4b) for driving the optical pulse generators (3a, 3b), and light from the measurement object are detected And a light detector (5) for obtaining detection light using the light pulse generated by the light pulse generator (3a, 3b), irradiating the measurement light with the detection light, and measuring The light detector (5) detects the transmitted light or reflected light from the object and performs spectroscopic analysis, and by controlling the frequency of the drive signal of each drive signal generator (4a, 4b), Output from the optical pulse generator (3a, 3b) Controlling the repetition frequency of that light pulse, by which to control the delay time relates to time-resolved spectroscopic method.

  A third aspect of the present invention is a terahertz wave generation system including a plurality of optical pulse generators (3) to which light from a continuous light source (2) is input, the plurality of optical pulse generators (3) And a drive signal generator (4) for driving each of the systems.

  This terahertz wave generation system can basically adopt any configuration of the time-resolved spectroscopy system described above in accordance with the known configuration of the terahertz wave generation system. As described above, by adopting the above configuration, the terahertz wave generation system of the present invention can effectively control the delay time, and can easily generate terahertz waves of various frequencies.

  In a preferred embodiment of the third aspect of the present invention, the optical pulse generator (3) includes a light input section (12), a branch section (13) for branching light input to the input section, and the branch A first waveguide (14) through which light branched from the section (13) propagates, a second waveguide (15) through which light different from the above branched from the branch section (13) propagates, A multiplexing unit (16) for combining optical signals output from the first waveguide and the second waveguide, and an output of an optical signal for outputting the optical signal combined by the multiplexing unit A waveguide portion (18) including a portion (17); and the drive signal generator (4) includes a first drive signal (19) for driving the first waveguide and the second drive signal generator (4). A drive signal system (21) for obtaining a second drive signal (20) for driving the waveguide of the first and a bias signal (22, 23) applied to the first waveguide and the second waveguide. Gain The bias signal system (24) for, including a; a system described above. By using such an optical pulse generator and driving signal generator, the delay time can be easily adjusted, and as a result, terahertz waves of various frequencies can be easily generated.

  A fourth aspect of the present invention is a time-resolved spectroscopic system (1) for detecting a terahertz wave, the first optical pulse generator to which light from a first continuous light source is input, and the first The first drive signal generator for driving the optical pulse generator of the above, the terahertz generator to which the optical pulse generated from the first optical pulse generator is incident, and the light from the second continuous light source are input The second optical pulse generator, the second drive signal generator for driving the second optical pulse generator, the optical pulse generated from the second optical pulse generator is incident, The present invention relates to a system including a terahertz detector that irradiates a measurement target with a terahertz wave generated from a terahertz generator and detects light from the measurement target.

  According to the present invention, it is possible to provide a time-resolved spectroscopic system and a spectroscopic method that are not easily affected by disturbance.

  According to the present invention, it is possible to provide a time-resolved spectroscopic system and a spectroscopic method capable of adjusting delay time while maintaining accuracy.

  According to the present invention, since the delay time can be adjusted easily and accurately, an effective terahertz wave generation system can be provided.

  Hereinafter, the present invention will be specifically described with reference to the drawings. FIG. 3 is a block diagram for explaining the time-resolved spectroscopy system of the present invention. As shown in FIG. 3, the first aspect of the present invention is a time-resolved spectroscopic system (1), an optical pulse generator (3) to which light from a continuous light source (2) is input, and the light A drive signal generator (4) for driving the pulse generator (3); and a photodetector (5) for detecting light from the object to be measured, the optical pulse generator (3 ) Is used to obtain detection light, irradiate the measurement object with the detection light, and the light detector (5) detects transmitted light or reflected light from the measurement object. The present invention relates to a time-resolved spectroscopic system that performs spectroscopic analysis. Examples of the detection light include pump light and probe light. Hereinafter, the description will be made based on pump-probe measurement. However, the time-resolved spectroscopy system of the present invention can be applied to time-resolved measurement such as four-wave mixing measurement. The drive signal from the drive signal generator (4) is preferably a high-frequency signal, and the frequency of the high-frequency signal is, for example, 1 GHz to 100 GHz.

  Examples of the continuous light source include a light source capable of outputting continuous light (CW), and a distributed feedback semiconductor laser (DFB laser). A constant light output operation type DFB laser is preferable because of its high single wavelength selectivity. The optical band may be not only the C-band but also the L-band on the long wave side or the S-band on the short wave side. The light intensity is 1 mW to 50 mW.

  By using the optical pulse generator (3) having the drive signal generator (4) in this way, a time-resolved spectroscopic system that does not use a resonator or the like can be provided. This makes it possible to provide a time-resolved spectroscopy system that is less susceptible to disturbances. Furthermore, by controlling the high-frequency signal with the drive signal generator (4), the repetition frequency of the optical pulse can be easily changed and adjusted easily, and the delay time can also be controlled easily. A spectroscopic system can be provided. In particular, a terahertz wave can be generated by adjusting the repetition frequency of an optical pulse from an optical pulse generator to generate an ultrashort pulse, and a time spectroscopy system using the terahertz wave can be provided. In this case, for example, a terahertz generator for generating a terahertz wave in the optical path may be installed. Specifically, an optical switch having an antenna may be installed in each optical pulse path to control the delay of each optical pulse.

  Also, as shown in FIG. 3, the preferred embodiment of the present invention further comprises intensity modulation means (7) for modulating the intensity of the continuous light source (2), and the intensity modulation means (7) The system according to the above, wherein the intensity-modulated continuous wave light is incident on the optical pulse generator (3), the intensity-modulated optical pulse is obtained, and spectral analysis is performed using the intensity-modulated optical pulse. .

  In the past, intensity modulation was performed using physical means such as an optical chopper. However, in this aspect, since the intensity modulation means (7) is provided, an intensity modulation signal can be obtained without physically performing light intensity modulation by shielding light. This makes it possible to provide a time-resolved spectroscopic system that is less susceptible to disturbances.

  Specifically, the continuous light source (2) is a semiconductor laser, and the intensity modulation means (7) is a modulation signal generator for driving the semiconductor laser. System. Specifically, a semiconductor laser is driven by a modulation signal generator and ON / OFF control is performed quickly.

  A preferred aspect of the present invention relates to any one of the above systems, further comprising an optical fiber for propagating an optical pulse signal generated from the optical pulse generator. The optical fiber may be used as an optical pulse generator that generates an optical pulse signal. By using an optical fiber, it is possible to irradiate a light pulse from the very vicinity of the object. Furthermore, by using an optical fiber, a light pulse can be emitted from an arbitrary place.

  FIG. 4 is a block diagram for explaining the time-resolved spectroscopy system of the present invention. As shown in FIG. 4, a preferred embodiment of the present invention includes a plurality of the optical pulse generators (3a, 3b), and drives each of the optical pulse generators (3a, 3b) at different repetition frequencies. , A time-resolved spectroscopic system that performs a delay time sweep.

  By using a plurality of optical pulse generators (3a, 3b), pump light and probe light can be obtained without using optical elements.

  A preferred embodiment of the present invention includes a plurality of the optical pulse generators (3), and outputs from the optical pulse generator (3) by controlling the frequency of the drive signal of each drive signal generator (4). The system according to any one of the above, wherein the delay time can be controlled by controlling the repetition frequency of the optical pulse to be generated.

  That is, in the time-resolved spectrometer as shown in FIG. 1, the delay time is controlled using a movable stage. However, the movable stage has poor time response and cannot be adjusted with high accuracy. In the above aspect, the delay time can be accurately controlled by a simple method of adjusting the drive signal of the optical pulse generator.

FIG. 5 is a diagram for explaining time-resolved spectroscopy according to the present invention. As shown in FIG. 5, when one optical pulse generator is driven at a frequency f ₁ and the other is driven at f ₂ , the time resolution is Δτ (tau) = 1 / f ₁ −1 / f ₂ . Determined. Where f ₂
> It is f _1. For example, when driving at f ₁ = 1 GHz and f ₂ = 1.001 GHz (frequency difference: 1 MHz), measurement can be performed with a time resolution of 100 fs. In addition, since these optical pulse generators can be driven independently, a set of pulse trains with different pulse light wavelengths can be generated simply by changing the wavelength of the input continuous light. Further, according to the present invention, an optical system for adjusting the two optical path lengths is not necessary. As a result, the system can be further simplified and a time-resolved spectroscopic system that is resistant to disturbances such as temperature and vibration can be constructed.

  FIG. 6 is a diagram showing an example of a preferable optical pulse generator of the present invention. As shown in FIG. 6, in a preferred embodiment of the present invention, the optical pulse generator (3) includes an optical input unit (12), a branching unit (13) for branching light input to the input unit, and , A first waveguide (14) through which the light branched from the branch section (13) propagates, and a second waveguide (15) through which another light branched from the branch section (13) propagates. A multiplexing unit (16) for combining optical signals output from the first waveguide and the second waveguide, and light for outputting an optical signal combined by the multiplexing unit A waveguide portion (18) including a signal output portion (17); and the drive signal generator (4) includes a first drive signal (19) for driving the first waveguide; A drive signal system (21) for obtaining a second drive signal (20) for driving the second waveguide, and a bias signal (2) applied to the first waveguide and the second waveguide , The bias signal system for obtaining a 23) and (24); a system according to the any one having a.

What is necessary is just to employ | adopt suitably what is used for optical SSB modulators etc. as said waveguide. The optical SSB modulator is an optical modulator that can obtain output light shifted by the frequency (f _m ) of the modulation signal (S. Shimotsu, S. Oikawa, T. Saitou, N. Mitsugi, K. Kubodera). , T. Kawanishi and M. Izutsu, “Single Side-Band Modulation Performance of a LiNbO ₃ Integrated Modulator Consisting of Four-Phase Modulator Wavegate,” IEEE Photon. Tech. Lett., Vol. 13, 364-366 (2001), “Shunitsu Shiichi, Izutsu Masayuki,“ LiNbO ₃ Optical SSB Modulator for Next Generation Communications ”, Optical Alliance, 2000.7. Pp. 27-30”).

  By using the above-described optical pulse generator and drive signal generator, it is possible to obtain an optical pulse that is extremely homogeneous and extremely responsive. As a result, it is possible to provide an extremely accurate time-resolved spectrometer.

In a preferred aspect of the present invention, the drive signal system (21) and the bias signal system (24) include the first drive signal (19), the second drive signal (20), and the bias signal (22, 23). Relates to the system described above, which is driven to satisfy the following formula (I).
ΔA + Δθ = π / 2 (I)
(Where ΔA and Δθ are defined as ΔA≡ (A ₁ −A ₂ ) / 2 and Δθ≡ (θ ₁ −θ ₂ ) / 2, respectively, where A ₁ and A ₂ are the first modulation electrodes, respectively. And the optical phase shift amplitude induced in the second modulation electrode, and θ ₁ and θ ₂ indicate the optical phase shift amount induced in the first waveguide and the second waveguide, respectively)

  As will be described later, by driving to satisfy the above formula (I), two phase modulators to be combined (a phase modulator is constituted by a waveguide and an electrode to which a drive signal is applied) are combined. The optical signals complement each other, and an optical pulse signal with good spectral characteristics can be obtained.

RF signals for driving each arm of the Maha-Zehnder modulator are RF-a and RF-b, respectively. RF-a and RF-b have amplitudes A _a (corresponding to A ₁ ) and A _b (corresponding to A ₂ ), respectively, and the modulation frequency is ω, the following equations (1 ) Can be expressed as:
RF-a = A _a sin ωt, RF-b = A _b sin ωt (1)

On the other hand, if the amplitude of the input light to the Mach-Zehnder modulator is E _in , the electric field E _out due to the output light of the Mach-Zehnder modulator can be expressed by Expression (2). In Equation (2), J _k (•) represents a k-th order Bessel function.

Next, the conversion efficiency eta _k, defined as a relative ratio with respect to the input light intensity P _in the k-th order frequency comb component intensity P _k. When the drive vibration is a large amplitude signal, that is, when A _i (t) (i = a or b) is sufficiently large, the conversion efficiency η _k can be approximated by the following equation (3).

However, / A (Aber), ΔA, and Δθ are each defined by the following equation (4).
/ A≡ (A ₁ + A ₂ ) / 2, ΔA≡ (A ₁ −A ₂ ) / 2, Δθ≡ (θ ₁ −θ ₂ ) / 2 (4)

Here, the condition for obtaining a flat spectral characteristic is when η _k does not depend on k, that is, when equation (3) is independent of the modulation order k. Therefore, the condition for obtaining a flat spectral characteristic is derived as equation (5).
ΔA + Δθ = π / 2 (5)
Therefore, a pulse light source having a flat spectral characteristic can be obtained by using the above optical pulse generator, and an optical pulse having a flat spectral characteristic can be obtained by driving the Mach-Zehnder modulator so as to satisfy Equation (5). It can be seen that can be obtained.

[Maximize conversion efficiency]
Next, a condition for maximizing the conversion efficiency η _k under this spectrum flattening condition is obtained. By substituting equation (5) into equation (3), the conversion efficiency η _k can be expressed by a simple equation such as the following equation (6).

Therefore, it can be seen that the conversion efficiency η _k is maximized when Expression (7) is satisfied.
ΔA = Δθ = π / 4 (7)
Then, the maximum conversion efficiency η _{k, max} when the expression (7) is satisfied can be expressed by the following expression (8).

  From the above, it can be said that the equation for obtaining a flat optical pulse by the Maha-Zehnder modulator is the equation (5) (ΔA + Δθ = π / 2). On the other hand, the optical pulse generation efficiency is maximized while satisfying the flattening conditional expression when the expression (7) (ΔA = Δθ = π / 4) which is the maximum efficient flattening condition is satisfied. Equation (7) means that the Maha-Zehnder modulator is biased at 2 / π point, and the maximum phase difference of the phase shift induced by the drive sine wave signals RF-a and RF-b is π.

  A second aspect of the present invention is a time-resolved spectroscopic method using a time-resolved spectroscopic system (1), wherein the time-resolved spectroscopic system (1) is a light pulse input by light from a continuous light source (2). A generator (3), a drive signal generator (4) for driving the optical pulse generator (3), and a photodetector (5) for detecting light from the measurement object Then, detection light is obtained using the light pulse generated by the light pulse generator (3), the detection light is irradiated onto the measurement object, and transmitted light or reflected light from the measurement object is used as the light detector. The present invention relates to a time-resolved spectroscopic method in which spectroscopic analysis is performed by detecting.

  In the above method, since the spectroscopic analysis can be performed without using an external resonator or the like, it is possible to provide a spectroscopic method which is not easily affected by disturbance.

  A preferred embodiment of the second aspect of the present invention is a time-resolved spectroscopic method using a time-resolved spectroscopic system (1), and the time-resolved spectroscopic system (1) receives light from a continuous light source (2). A plurality of optical pulse generators (3a, 3b), a drive signal generator (4a, 4b) for driving the optical pulse generators (3a, 3b), and light from the measurement object are detected And a light detector (5) for obtaining detection light using the light pulse generated by the light pulse generator (3a, 3b), irradiating the measurement light with the detection light, and measuring The light detector (5) detects the transmitted light or reflected light from the object and performs spectroscopic analysis, and by controlling the frequency of the drive signal of each drive signal generator (4a, 4b), Output from the optical pulse generator (3a, 3b) Controlling the repetition frequency of the optical pulses, thereby controlling the delay time relates to time-resolved spectroscopic method.

  A third aspect of the present invention is a terahertz wave generation system including a plurality of optical pulse generators (3) to which light from a continuous light source (2) is input, the plurality of optical pulse generators (3) And a drive signal generator (4) for driving each of the systems.

  This terahertz wave generation system can basically adopt any configuration of the time-resolved spectroscopy system described above in accordance with the known configuration of the terahertz wave generation system. As described above, by adopting the above configuration, the terahertz wave generation system of the present invention can effectively control the delay time, and can easily generate terahertz waves of various frequencies.

  As the terahertz wave generation system, a known system disclosed in, for example, US Pat. No. 5,401,953 can be used as appropriate. Specifically, an optical switch element using an optical switch array such as an array and a voltage control device are included. The optical switch element includes a transmission line and an optical switch including a minute dipole antenna installed between the transmission lines. For example, the transmission line is commonly connected to all the optical switches, and is connected to the voltage control device by a lead wire. On the other hand, the transmission line is divided with respect to each optical switch, and each is connected to the voltage control device by a lead wire. With such a configuration, the voltage applied to the optical switch by the voltage control device can be set and controlled separately.

  Each optical switch also has a function as an antenna that outputs a terahertz wave. When a light pulse from an optical pulse light source is incident, a pulsed current flows, thereby generating and outputting a terahertz wave from each optical switch. Is done.

  In a preferred embodiment of the third aspect of the present invention, the optical pulse generator (3) includes a light input section (12), a branch section (13) for branching light input to the input section, and the branch A first waveguide (14) through which light branched from the section (13) propagates, a second waveguide (15) through which light different from the above branched from the branch section (13) propagates, A multiplexing unit (16) for combining optical signals output from the first waveguide and the second waveguide, and an output of an optical signal for outputting the optical signal combined by the multiplexing unit A waveguide portion (18) including a portion (17); and the drive signal generator (4) includes a first drive signal (19) for driving the first waveguide and the second drive signal generator (4). A drive signal system (21) for obtaining a second drive signal (20) for driving the waveguide of the first and a bias signal (22, 23) applied to the first waveguide and the second waveguide. Gain The bias signal system (24) for, including a; a system described above. By using such an optical pulse generator and driving signal generator, the delay time can be easily adjusted, and as a result, terahertz waves of various frequencies can be easily generated.

  A fourth aspect of the present invention is a time-resolved spectroscopic system (1) for detecting a terahertz wave, the first optical pulse generator to which light from a first continuous light source is input, and the first The first drive signal generator for driving the optical pulse generator of the above, the terahertz generator to which the optical pulse generated from the first optical pulse generator is incident, and the light from the second continuous light source are input The second optical pulse generator, the second drive signal generator for driving the second optical pulse generator, the optical pulse generated from the second optical pulse generator is incident, The present invention relates to a system including a terahertz detector that irradiates a measurement target with a terahertz wave generated from a terahertz generator and detects light from the measurement target. By controlling the respective drive signals and setting the drive frequency of the optical pulse generator to satisfy the required time resolution according to Δτ (tau), time-resolved spectroscopic measurement can be performed.

FIG. 7 is a block diagram showing a time-resolved spectroscopy system in the first embodiment. In this time-resolved spectroscopic system, the optical pulse generator is driven by a high-frequency sine wave signal. Then, the laser light from the semiconductor laser subjected to direct modulation is incident on the optical pulse generator. The generated light pulse is branched by a beam splitter, and one is reflected by a mirror fixed to a movable stage. A time delay is obtained with respect to the other optical pulse by continuously sweeping the movable stage. Then, these light pulses are applied to the detection target, and transmitted light or reflected light is detected by a photodetector (not shown). In this way, time-resolved spectroscopy can be performed. According to this time-resolved spectroscopic system, measurement can be performed with timing jitter suppressed. In addition, according to the time-resolved spectroscopic system, the light intensity modulator is not required, so that the system can be simplified.

FIG. 8 is a block diagram showing a time-resolved spectroscopic system according to the second embodiment. As shown in FIG. 8, this time-resolved spectroscopic system generates optical pulses by driving two optical pulse light sources with sinusoidal signals having different frequencies. One is a pump light pulse and the other is a probe light pulse. Each light pulse can be made into a light pulse having a shorter time width such as femtosecond by entering a nonlinear compression fiber, for example. That is, a preferred embodiment of the present invention is to input the output light from the optical pulse generator to the fiber and irradiate the detection target with the output light from the fiber. The pump and probe light pulses are incident on the object to be detected, and the transmitted light or reflected light of the probe light pulse is detected by a photodetector. As this photodetector, one having a band covering the repetition frequency of the probe light is preferable. Time-resolved spectroscopic measurement can be performed by setting the drive frequency of the optical pulse generator to satisfy the required time resolution according to Δτ (tau). By using this method, a movable stage and an optical system for adjusting the optical path lengths of both pulse lights are not required, and stable measurement can be performed against disturbance. In addition, by changing the semiconductor laser and the drive signal frequency, time-resolved measurement with improved controllability of the wavelength and repetition frequency of the optical pulse can be performed.

Terahertz Wave Generation / Detection Method FIG. 9 is a diagram for explaining a terahertz wave generation / detection method. That is, it shows that terahertz waves can be detected by using the time-resolved spectroscopy system of the present invention. As shown in FIG. 9, an optical pulse generator, a terahertz generator, a terahertz detector, and a terahertz wave optical system are provided. A light pulse from the first light source is incident on the terahertz generator to generate a terahertz wave. The generated terahertz wave is guided to a terahertz detector using a terahertz optical system. A light pulse from the second light source is incident on the terahertz detector and a terahertz wave is detected. Time-resolved spectroscopic measurement can be performed by setting the drive frequency of the optical pulse generator to satisfy the required time resolution according to Δτ (tau).

  The present invention can be suitably used in fields such as the spectroscopic analysis device industry.

  The present invention can be suitably used in fields such as optical information communication.

  The present invention can also be used for generation and detection of electromagnetic waves in the terahertz region (100 GHz to 10 THz) and spectroscopy using ultrashort light pulses.

FIG. 1 is a block diagram illustrating a configuration example of a conventional time-resolved spectrometer. FIG. 2 is a block diagram showing a configuration example of a conventional time-resolved spectroscopic device, which is different from that shown in FIG. FIG. 3 is a block diagram for explaining the time-resolved spectroscopy system of the present invention. FIG. 4 is a block diagram for explaining the time-resolved spectroscopy system of the present invention. FIG. 5 is a diagram for explaining time-resolved spectroscopy according to the present invention. FIG. 6 is a diagram showing an example of a preferable optical pulse generator of the present invention. FIG. 7 is a block diagram illustrating the time-resolved spectroscopy system in the first embodiment. FIG. 8 is a block diagram illustrating a time-resolved spectroscopy system according to the second embodiment. FIG. 9 is a diagram for explaining a terahertz wave generation / detection method.

Explanation of symbols

1 time-resolved spectroscopic system, 2 continuous light source, 3 optical pulse generator, 4 drive signal generator, 5 photodetector, 7 intensity modulation means

Claims (13)

A time-resolved spectroscopy system (1),

An optical pulse generator (3) that receives light from the continuous light source (2);
A drive signal generator (4) for driving the optical pulse generator (3);
A photodetector (5) for detecting light from the measurement object;
Comprising

Detection light is obtained by using the light pulse generated by the optical pulse generator (3), the detection light is irradiated onto the measurement object, and transmitted light or reflected light from the measurement object is applied to the optical detector (5). ) To detect spectroscopic analysis,

Time-resolved spectroscopy system. Furthermore, it comprises intensity modulation means (7) for modulating the intensity of the continuous light source (2),

The continuous wave light intensity-modulated by the intensity modulation means (7) is incident on the optical pulse generator (3) to obtain an intensity-modulated light pulse, and a spectral analysis is performed using the intensity-modulated light pulse. Do,

The system of claim 1. The continuous light source (2) is a semiconductor laser;
The intensity modulation means (7) is a modulation signal generator for driving the semiconductor laser;
The system according to claim 2.   The system of claim 1, further comprising an optical fiber that propagates an optical pulse signal generated from the optical pulse generator. Including a plurality of the optical pulse generators (3),

The system according to claim 1, wherein a delay time sweep is performed by driving each said optical pulse generator (3) at a different repetition frequency. Including a plurality of the optical pulse generators (3),
By controlling the frequency of the drive signal of each drive signal generator (4), the repetition frequency of the optical pulse output from the optical pulse generator (3) can be controlled, thereby controlling the delay time. The system of claim 1. The optical pulse generator (3)
A light input section (12), a branch section (13) from which light input to the input section branches, a first waveguide (14) through which light branched from the branch section (13) propagates, The second waveguide (15) through which light different from the above branched from the branching section (13) propagates, and the optical signals output from the first waveguide and the second waveguide are combined. And a waveguide section (18) including an optical signal output section (17) for outputting an optical signal multiplexed by the multiplexing section;

The drive signal generator (4)
A drive signal system (21) for obtaining a first drive signal (19) for driving the first waveguide and a second drive signal (20) for driving the second waveguide;
A bias signal system (24) for obtaining a bias signal (22, 23) to be applied to the first waveguide and the second waveguide;

The system of claim 1. The drive signal system (21) and the bias signal system (24) have the first drive signal (19), the second drive signal (20) and the bias signal (22, 23) represented by the following formula (I): The system of claim 7, wherein the system is driven to satisfy.
ΔA + Δθ = π / 2 (I)
(Where ΔA and Δθ are defined as ΔA≡ (A ₁ −A ₂ ) / 2 and Δθ≡ (θ ₁ −θ ₂ ) / 2, respectively, where A ₁ and A ₂ are the first modulation electrodes, respectively. And the optical phase shift amplitude induced in the second modulation electrode, and θ ₁ and θ ₂ indicate the optical phase shift amount induced in the first waveguide and the second waveguide, respectively) A time-resolved spectroscopic method using a time-resolved spectroscopic system (1),

The time-resolved spectroscopy system (1)
An optical pulse generator (3) that receives light from the continuous light source (2);
A drive signal generator (4) for driving the optical pulse generator (3);
A photodetector (5) for detecting light from the measurement object;
Comprising

Detection light is obtained by using the light pulse generated by the optical pulse generator (3), the detection light is irradiated onto the measurement object, and transmitted light or reflected light from the measurement object is applied to the optical detector (5). ) To detect spectroscopic analysis,

Time-resolved spectroscopy. A time-resolved spectroscopic method using a time-resolved spectroscopic system (1),

The time-resolved spectroscopy system (1)
A plurality of optical pulse generators (3a, 3b) for receiving light from the continuous light source (2);
Drive signal generators (4a, 4b) for driving the optical pulse generators (3a, 3b);
A photodetector (5) for detecting light from the measurement object;
Comprising

Detection light is obtained using light pulses generated by the light pulse generators (3a, 3b), the detection light is irradiated onto the measurement object, and transmitted light or reflected light from the measurement object is applied to the light detector. (5) detects and performs spectroscopic analysis,
By controlling the frequency of the drive signal of each drive signal generator (4a, 4b), the repetition frequency of the optical pulse output from the optical pulse generator (3a, 3b) is controlled. Control

Time-resolved spectroscopy. A terahertz wave generation system comprising a plurality of optical pulse generators (3) to which light from a continuous light source (2) is input,

A drive signal generator (4) for driving each of the plurality of optical pulse generators (3) is provided,

system. The optical pulse generator (3)
A light input section (12), a branch section (13) from which light input to the input section branches, a first waveguide (14) through which light branched from the branch section (13) propagates, The second waveguide (15) through which light different from the above branched from the branching section (13) propagates, and the optical signals output from the first waveguide and the second waveguide are combined. And a waveguide section (18) including an optical signal output section (17) for outputting an optical signal multiplexed by the multiplexing section;

The drive signal generator (4)
A drive signal system (21) for obtaining a first drive signal (19) for driving the first waveguide and a second drive signal (20) for driving the second waveguide;
A bias signal system (24) for obtaining a bias signal (22, 23) to be applied to the first waveguide and the second waveguide;

The system of claim 11. A time-resolved spectroscopy system (1) for detecting terahertz waves,

A first optical pulse generator to which light from a first continuous light source is input;
A first drive signal generator for driving the first optical pulse generator;
A terahertz generator on which an optical pulse generated from the first optical pulse generator is incident;

A second optical pulse generator for receiving light from the second continuous light source;
A second drive signal generator for driving the second optical pulse generator;
A terahertz detector that receives an optical pulse generated from the second optical pulse generator, irradiates the terahertz wave generated from the terahertz generator to the measurement object, and detects light from the measurement object

A system comprising:

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