Patent Description:
The present invention relates to the technical field of spectral detection, more particularly to a device and a spectrometer for quantitatively detecting carbon <NUM> isotope by a dual-wavelength method.

As the only radioactive carbon isotope in nature, the carbon <NUM> isotope has a half-life of about <NUM> years. It is mainly produced by the interaction of cosmic rays with nitrogen in the earth's atmosphere, and the isotope abundance thereof in the earth's atmosphere is only <NUM>-<NUM>.

Carbon <NUM> in the earth's atmosphere mainly exists in the form of <NUM>CO<NUM> gas, which diffuses through the global biological carbon cycle. The content of Carbon <NUM> is basically stable, and is widely used in the fields of dating and tracing, forensic identification, environmental monitoring, drug metabolism, etc..

At present, laser spectroscopy is one of the important methods for the detection of carbon <NUM> isotope, and has great application potential in the quantitative detection of carbon <NUM> isotope. The main measurement principle of laser spectroscopy is to control the sample at a low temperature of <NUM>, and use the optical cavity ring-down spectroscopy method to measure the spectral signal of the carbon <NUM> isotope.

However, this laser spectroscopy method is limited by the Doppler linewidth of the spectrum itself, and cannot effectively distinguish the spectra of carbon <NUM> isotope from that of other carbon isotopes, or the spectra of carbon <NUM> isotope from that of other molecular isotopes, i.e., it is difficult to achieve accurate quantitative measurement.

In view of this, in order to solve the above-described problems, the present invention provides a device for quantitatively detecting carbon <NUM> isotope by a dual-wavelength method in accordance with claim <NUM>, and a spectrometer comprising the device. The technical solution is as follows:.

A device for quantitatively detecting carbon <NUM> isotope by a dual-wavelength method, wherein.

Preferably, in the above device, the tuning bandwidth of the pump light is greater than <NUM>;
the tuning bandwidth of the probe light is greater than <NUM>.

Preferably, in the above device, the first laser locking module is used to lock the pump light in the optical cavity of the sample chamber, wherein:.

Preferably, in the above device, the pump light and the probe light are collinear in the sample chamber.

Preferably, in the above device, the optical cavity is a high-finesse optical cavity, and the finesse is greater than <NUM>,<NUM>.

Preferably, in the above device, the cavity length adjusting unit is a piezoelectric ceramic unit.

Preferably, in the above device, the sample chamber further comprises a temperature control unit;.

Preferably, in the above device, the signal detecting module comprises a detecting unit;.

Preferably, in the above device, the signal detecting module further comprises: a timing control unit;
wherein the timing control unit is used to control the working states of the cavity length adjusting unit and the detecting unit.

A spectrometer, the spectrometer comprising the device described in any of the above.

The terms "first mid-infrared laser" and "second mid-infrared laser" used in the following designate the pump light and the probe light, respectively.

Compared with the prior art, the present invention realizes the following beneficial effects:
the present invention provides a device for quantitatively detecting carbon <NUM> isotope by a dual-wavelength method. Two mid-infrared lasers with different wavelengths are locked in an optical cavity of a sample chamber, so that the two mid-infrared lasers are collinear. The cavity length of the optical cavity is adjusted by the cavity length adjusting unit, to tune the mode frequency of the optical cavity, and then tune the frequencies of the two mid-infrared lasers, so that the frequencies of the two mid-infrared lasers match with different energy levels of the target isotope molecule simultaneously. After the frequencies of the mid-infrared lasers and the energy levels of the target isotope molecule are matched simultaneously, the target isotope molecule is excited by two mid-infrared lasers simultaneously, and the optical cavity output signal of the second mid-infrared laser passing through the optical cavity is detected. That is to say, since the excitation of the target isotope molecule and the detection of the spectrum require two lasers to match with different energy levels of the target isotope molecule simultaneously, it greatly improves the selectivity of the spectral detection, thereby improving the spectral resolution ability, i.e., achieving the selection and resolution of the target isotope molecule.

In order to illustrate the embodiments of the present invention or the technical solutions in the prior art more clearly, the drawings that are applied in the embodiments or the description of the prior art will be briefly introduced below. Obviously, the drawings show only exemplary embodiments of the invention or comparative examples.

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings of the embodiments of the present invention. Obviously, the described embodiments are only a part of the embodiments of the present invention, rather than all the embodiments. Based on the embodiments of the present invention, all other embodiments obtained by those of ordinary skill in the art without creative work shall fall within the protection scope of the present invention.

In order to make the above objects, features and advantages of the present invention more clearly understood, the present invention will be described in further detail below with reference to the drawings and embodiments.

Referring to <FIG> is a schematic structural diagram of a device for quantitatively detecting carbon <NUM> isotope by a dual-wavelength method.

The device comprises: a first laser source <NUM>, a second laser source <NUM>, a first laser locking module <NUM>, a second laser locking module <NUM>, a sample chamber <NUM> and a signal detecting module <NUM>. The device does not include a cavity length adjusting unit inside the sample chamber <NUM>, and thus is excluded from the embodiments of the present invention.

The first laser source <NUM> is used to output a continuous first mid-infrared laser; the second laser source <NUM> is used to output a continuous second mid-infrared laser; the wavelengths of the first mid-infrared laser and the second mid-infrared laser are different.

The first laser locking module <NUM> is used to lock the first mid-infrared laser in the optical cavity of the sample chamber <NUM>; the second laser locking module <NUM> is used to lock the second mid-infrared laser in the optical cavity of the sample chamber <NUM>; it should be noted that after the first mid-infrared laser and the second mid-infrared laser are locked in the optical cavity of the sample chamber <NUM>, the first mid-infrared laser and the second mid-infrared laser are collinear in the sample chamber.

Referring to <FIG> is a schematic structural diagram of another device for quantitatively detecting carbon <NUM> isotope by a dual-wavelength method according to an embodiment of the present invention.

The sample chamber <NUM> at least comprises a cavity length adjusting unit <NUM>.

The cavity length adjusting unit <NUM> is used to adjust the cavity length of the optical cavity, to tune the mode frequency of the optical cavity, and then tune the frequencies of the first mid-infrared laser and the second mid-infrared laser, so that the frequency of the first mid-infrared laser and the frequency of the second mid-infrared laser match with different energy levels of the target isotope molecule simultaneously.

The signal detecting module <NUM> is used to detect the optical cavity output signal of the second mid-infrared laser passing through the optical cavity after the laser frequencies and the energy levels of the target isotope molecule are matched simultaneously.

In this embodiment, referring to <FIG> is an energy level matching diagram of a device for quantitatively detecting carbon <NUM> isotope by a dual-wavelength method according to an embodiment of the present invention.

The first laser source <NUM> is mainly used to provide pump light that matches with the energy levels E1 and E2 of the target isotope molecule as shown in <FIG>, i.e., the first mid-infrared laser defined in the present invention.

After the first laser source <NUM> outputs a continuous first mid-infrared laser, the first mid-infrared laser is adjusted by the first laser locking module <NUM>, to ensure that the first mid-infrared laser can be locked in the optical cavity of the sample chamber <NUM>, so that the frequency of the first mid-infrared laser is consistent with one of the mode frequencies of the optical cavity.

The second laser source <NUM> is mainly used to provide probe light that matches with the energy levels E2 and E3 of the target isotope molecule as shown in <FIG>, i.e., the second mid-infrared laser defined in the present invention.

After the second laser source <NUM> outputs a continuous second mid-infrared laser, the second mid-infrared laser is adjusted by the second laser locking module <NUM>, to ensure that the second mid-infrared laser can also be locked in the optical cavity of the sample chamber <NUM>, so that the frequency of the second mid-infrared laser is consistent with another one of the mode frequencies of the optical cavity.

Further, by the cavity length adjusting unit <NUM>, the adjustment of the cavity length of the optical cavity of the sample chamber <NUM> is realized. The mode frequency of the optical cavity is changed by the adjustment of the cavity length, to further tune the frequencies of the first mid-infrared laser and the second mid-infrared laser, so that the frequency of the first mid-infrared laser matches with the energy levels E1 and E2 of the target isotope molecule, and the frequency of the second mid-infrared laser matches with the energy levels E2 and E3 of the target isotope molecule; i.e., the frequency of the first mid-infrared laser and the frequency of the second mid-infrared laser match with different energy levels of the target isotope molecule simultaneously.

After the frequency of the first mid-infrared laser and the frequency of the second mid-infrared laser match with different energy levels of the target isotope molecule simultaneously, the signal detecting module <NUM> is used to detect the optical cavity output signal of the second mid-infrared laser passing through the optical cavity, i.e., the transmission signal of the second mid-infrared laser passing through the optical cavity.

It should be noted that detecting the optical cavity output signal of the second mid-infrared laser passing through the optical cavity can be: any one of the cavity enhanced absorption spectroscopy signal, the cavity ring-down spectroscopy signal, and the noise-immune cavity enhanced optical heterodyne molecular spectroscopy signal.

It can be known that since the excitation of the target isotope molecule and the detection of the spectrum require two lasers to match with different energy levels of the target isotope molecule simultaneously, the device for quantitatively detecting carbon <NUM> isotope by a dual-wavelength method according to the present invention greatly improves the selectivity of spectral detection, thereby improving the spectral resolution ability, and achieving the quantitative detection of carbon <NUM>.

Moreover, compared with the traditional laser spectroscopy method, it has high resolution and can realize the quantitative detection of carbon <NUM> isotope at room temperature.

That is to say, the device for quantitatively detecting carbon <NUM> isotope by a dual-wavelength method according to the present invention uses the idea of dual-wavelength energy levels matching to achieve the selection and resolution of the target isotope molecule, effectively distinguishing the spectra of carbon <NUM> isotope from that of other carbon isotopes, and the spectra of carbon <NUM> isotope from that of other molecular isotopes.

Further, based on the above embodiment of the present invention, the tuning bandwidth of the first mid-infrared laser is greater than <NUM>;
the tuning bandwidth of the second mid-infrared laser is greater than <NUM>.

In this embodiment, the output wavelength of the first mid-infrared laser has the function of fast tuning, and the tuning bandwidth thereof is greater than <NUM>.

The output wavelength of the second mid-infrared laser also has the function of fast tuning, and the tuning bandwidth thereof is greater than <NUM>.

Further, based on the above embodiment of the present invention, the first laser locking module <NUM> is used to lock the first mid-infrared laser in the optical cavity of the sample chamber <NUM>, comprising:.

Further, based on the above embodiment of the present invention, the second laser locking module <NUM> is used to lock the second mid-infrared laser in the optical cavity of the sample chamber <NUM>, comprising:.

In this embodiment, the first mid-infrared laser and the second mid-infrared laser need to be locked in the optical cavity of the sample chamber <NUM> simultaneously.

It should be noted that after the first mid-infrared laser and the second mid-infrared laser are locked in the optical cavity of the sample chamber <NUM>, the first mid-infrared laser and the second mid-infrared laser are collinear in the sample chamber.

Further, based on the above embodiment of the present invention, the optical cavity is a high-finesse optical cavity, and the finesse is greater than <NUM>,<NUM>.

In this embodiment, the optical cavity of the sample chamber <NUM> is a high-finesse optical cavity, and the typical value of its finesse is greater than <NUM>,<NUM>.

Further, based on the above embodiment of the present invention, the cavity length adjusting unit <NUM> is a piezoelectric ceramic unit.

In this embodiment, a piezoelectric ceramic unit is used to adjust the cavity length of the high-fineness optical cavity, which can improve the precision of the cavity length adjusting.

Further, based on the above embodiment of the present invention, referring to <FIG> is a schematic structural diagram of another device for quantitatively detecting carbon <NUM> isotope by a dual-wavelength method according to an embodiment of the present invention.

The sample chamber <NUM> further comprises a temperature control unit <NUM>;.

In this embodiment, the temperature control unit <NUM> is mainly used to realize the temperature control of the high-fineness optical cavity, and the fluctuation range of the temperature of the optical cavity after temperature control needs to be less than 100mK.

The signal detecting module <NUM> comprises a detecting unit <NUM>;
the detecting unit <NUM> is used to detect the optical cavity output signal of the second mid-infrared laser passing through the optical cavity, i.e., the transmission signal of the second mid-infrared laser passing through the optical cavity.

The detecting unit <NUM> detects the output signal of the optical cavity, which can be any one of the cavity enhanced absorption spectroscopy signal, the cavity ring-down spectroscopy signal, and the noise-immune cavity enhanced optical heterodyne molecular spectroscopy signal.

The signal detecting module <NUM> further comprises: a timing control unit <NUM>;
wherein the timing control unit <NUM> is used to control the working states of the cavity length adjusting unit and the detecting unit <NUM>.

In this embodiment, the timing control unit <NUM> controls the cavity length adjusting unit <NUM> (a piezoelectric ceramic unit) to adjust the cavity length of the optical cavity, and controls the detecting unit <NUM> to detect the optical cavity output signal of the second mid-infrared laser passing through the optical cavity after the frequency of the first mid-infrared laser and the frequency of the second mid-infrared laser match with different energy levels of the target isotope molecule simultaneously.

Further, after the detection period ends, the timing control unit <NUM> is further used to control the cavity length adjusting unit <NUM> (a piezoelectric ceramic unit) to continue to adjust the cavity length of the optical cavity, so that the first mid-infrared laser and the second mid-infrared laser restarts to match with the optical cavity modes and the energy levels corresponding to the target isotope molecule.

Further, based on all the above embodiments of the present invention, another embodiment of the present invention also provides a spectrometer. The spectrometer comprises the devices for quantitatively detecting carbon <NUM> isotope by a dual-wavelength method according to the above embodiments of the present invention.

The spectrometer has the excellent characteristics of the device for quantitatively detecting carbon <NUM> isotope by a dual-wavelength method.

The device and the spectrometer for quantitatively detecting carbon <NUM> isotope by a dual-wavelength method have been described in detail above. Herein, specific examples are used to illustrate the principles and implementations of the present invention. The descriptions of the above examples are only used to help understand the methods and the core idea of the present invention. Furthermore, those of ordinary skill in the art can make modifications within the scope of the invention, which is defined by the appended claims.

It should be noted that each embodiment in this specification is described in a progressive manner, and each embodiment focuses on the differences from other embodiments. The same and similar parts among all the embodiments can be referred to each other. As for the devices disclosed in the embodiments, since they correspond to the methods disclosed in the embodiments, the description is relatively simple. The relevant part can be referred to the description of the method.

It should also be noted that herein, relational terms such as first and second are only used to distinguish one entity or operation from another entity or operation, and do not necessarily require or imply any such actual relationship or order among these entities or operations. Furthermore, the terms "comprising", "including" or any other variations thereof are intended to encompass a non-exclusive inclusion such that elements inherent to a process, a method, an article, or a device of a list of elements are included, or elements inherent to a process, a method, an article, or a device are included. Without further limitation, an element qualified by the phrase "comprising a. " does not preclude the presence of additional identical elements in a process, a method, an article or a device that includes the element.

Claim 1:
A device for quantitatively detecting carbon <NUM> isotope by a dual-wavelength method, wherein the device comprises: a first laser source (<NUM>), a second laser source (<NUM>), a first laser locking module (<NUM>), a second laser locking module (<NUM>), a sample chamber (<NUM>) and a signal detecting module (<NUM>);
the first laser source (<NUM>) is configured to output a continuous pump light; the second laser source (<NUM>) is configured to output a continuous probe light; wherein the pump light and the probe light are mid-infrared laser light with different wavelengths;
the first laser locking module (<NUM>) is configured to lock the pump light in the optical cavity of the sample chamber (<NUM>); the second laser locking module (<NUM>) is configured to lock the probe light in the optical cavity of the sample chamber (<NUM>);
the sample chamber (<NUM>) at least comprises a cavity length adjusting unit (<NUM>);
the cavity length adjusting unit (<NUM>) is configured to tune the mode frequency of the optical cavity by adjusting the cavity length of the optical cavity, wherein:
the frequency of the pump light, as adjusted by the first laser locking module, is consistent with one of the mode frequencies of the optical cavity and matches with an energy difference between a first energy level E1 and a second energy level E2 of a target isotope molecule, the target isotope molecule being a molecule containing carbon <NUM> isotope,
and the frequency of the probe light, as adjusted by the second laser locking module, is consistent with another one of the mode frequencies of the optical cavity and matches with an energy difference between the second energy level E2 and a third energy level E3 of the target isotope molecule;
the signal detecting module (<NUM>) is configured to detect the optical cavity output signal of the probe light passing through the optical cavity after the laser frequencies and the energy levels of the target isotope molecule are matched simultaneously.