RU2730405C1 - M-dls martian multichannel diode-laser spectrometer - Google Patents

Abstract

FIELD: measurement.SUBSTANCE: invention relates to the field of measurement equipment and concerns a Martian multichannel diode-and-laser spectrometer M-DLS. Spectrometer consists of analytical gas volume based on optical multi-pass cuvette, set of monochromatic diode lasers with distributed feedback with periodic tuning of optical frequency of probing radiation in a range covering individual oscillation-rotational absorption lines of a given molecule and its isotopologues, and a photodetector. Analytical gas volume used is an optical multi-pass cell of a full optical intracavity output, which is an optical resonator with a mirror reflection coefficient of not less than 0.999 and the number of effective full passes of the probing beam through the analytical gas volume of the cuvette, which increases the effective optical path to such a distance, at which precision measurements of chemical and isotopic composition of a dusty atmosphere are provided. Reference channel for stabilizing the radiation frequency of lasers based on selected absorption lines employs said optical multi-pass analytical gas cell.EFFECT: technical result is higher sensitivity of device.1 cl, 3 dwg, 1 tbl

Description

The invention relates to the field of measuring technology and is intended for precision measurement of the chemical and isotopic composition of a dusty atmosphere and can be used to measure the chemical and isotopic composition of the surrounding atmospheres of planets, including the atmospheres of Mars and Earth in a wide range of thermodynamic parameters.

Known gas analytical devices, which are based on the method of high-resolution diode laser spectroscopy. So, in the patent of the Russian Federation No. RU 8674 G01N 27/12 2009, a useful model of a device for determining the molecular sorption properties of a substance is described, including a sealed chamber for a sample of a substance, a diode-laser spectrometer with a serially connected measuring cell and an executive control and data collection unit , while the measuring cuvette of the diode-laser spectrometer is connected to the unit for dosed steam supply and the control unit for vacuum pumping.

In Russian Patent № RU 123954 G01N 21/35 2012 discloses a laser optical system for measuring the isotope ratio ¹³ CO ^_2/12 CO _2, consisting of a laser, and installed along the radiation divider, an optical cell, a reference cell, photodetectors, and a computer system, while the optical cell is made in the form of a multi-pass optical Herriot cell with a means for regulating temperature stabilization.

RF patent RU 121927 2012 describes a high-resolution heterodyne fiber-optic spectroradiometer for remote passive analysis of the composition and state of the atmosphere. US patent US 9506804 2013 presents a gas analyzer based on the method of laser spectroscopy, operating on an open optical path.

EU patent EA 201391182 describes a device for measuring the concentrations of CO, NO, NO ₂ in a gas atmosphere at temperatures above 1200 ° C. All these devices are characterized by the following characteristics: high spectral resolution (laser line width of about 10 MHz at an operating frequency of about 10 ¹³ -10 ¹⁴ Hz), high sensitivity (detection threshold less than 1 ppmv, in some cases, taking into account enrichment, less than 1 ppbv ), a relatively narrow spectral range corresponding to the tuning of diode lasers (on the order of 1 cm ^-1 ), which is compensated by multichannel. At the same time, the sensitivity of these devices is limited by the length of the effective optical path in the analytical cell, as a rule, not exceeding several tens of meters, which is a serious disadvantage when performing isotopic measurements. A further increase in the optical path of multipass cells of the Herriot type leads to instability of the optical path and the impossibility of using such devices as part of autonomous robotic systems in a dusty atmosphere.

The closest technical solution for the same purpose to the claimed invention is a Tunable Laser Spectrometer, developed for operation as part of the SAM complex of the Curiosity rover and described in the article by Webster & Mahhafy 2009. In this device, the task of obtaining maximum sensitivity was solved by using a multi-pass cell of the Herriot system and enriching the gas sample by adsorbing carbon dioxide in special cells.

The disadvantage of the known technical solution is the insufficient length of the effective optical path in the analytical cell, which did not allow achieving the required sensitivity and led to an ambiguous interpretation of the measurement results.

The objective of the claimed invention is to increase the length of the effective optical path in an analytical gas cell to increase sensitivity.

The specified technical result is achieved by the fact that in a device consisting of an analytical volume based on a multi-pass analytical gas cell, a set of monochromatic diode lasers with distributed feedback with periodic tuning of the optical frequency of the probe radiation in the range covering individual vibrational-rotational absorption lines of a given molecule and its isotopologues as an analytical volume, a multi-pass analytical gas cell of a full resonator outlet is used, which is a hollow cylindrical volume, at the ends of which mirrors with a reflection coefficient of at least 0.999 are installed and the effective length of the optical path in which can reach values from 200 to 1000 m, both the mirror is partially permeable. This cell is also used as a reference channel for long-term stabilization of the laser radiation frequency along the selected absorption lines.

The essence of the invention is illustrated in Figures 1-3, which show the appearance and functional diagrams of the "Martian multichannel diode laser spectrometer (M-DLS)" for measuring the chemical and isotopic composition of planetary atmospheres. The M-DLS device is a diode-laser absorption spectrometer operating in several spectral channels in the IR spectral region of the 2-3 μm range. M-DLS provides a scientific task based on spectroscopic measurements of the optical molecular absorption of a gas sample of the surrounding atmosphere. Structurally, the device is a monoblock with a retractable air intake tube for taking an atmospheric gas sample at a level up to 0.5 m above the device location. The instrumental base of the M-DLS device is a multichannel atmospheric measurement module based on optical spectroscopic analysis of the composition of a gas sample from the local atmosphere delivered to an analytical multi-pass optical cell of the device.

The operation of the atmospheric measurement module (MAI) of the M-DLS device is ensured by its functional units:

многопроходная оптическая аналитическая газовая кювета полного внутрирезонаторного выхода (МОК) с оптическими и газовыми интерфейсами, включающими монохроматичные диодные лазеры с распределенной обратной связью (РОС-лазеры), фотоприемник с предварительным усилителем его фотоотклика, газовые соединители, нагреватель, датчики давления и температуры;

multi-pass optical analytical gas cell with full intracavity output (MOC) with optical and gas interfaces including monochromatic diode lasers with distributed feedback (DFB lasers), a photodetector with a preamplifier of its photoresponse, gas connectors, a heater, pressure and temperature sensors;

система формирования атмосферных проб (СФАП), включающая воздухозаборное устройство, внутреннюю газовую транспортную систему, газовую магистраль (ГМ) и клапаны;

Atmospheric sample formation system (SFAP), including an air intake device, an internal gas transport system, a gas pipeline (GM) and valves;

вычислительная управляющая система (ВУС), образованная микропроцессорной электронной платой интерфейсов и служебных систем и микропроцессорной платой модуля атмосферных измерений;

a computer control system (VUS) formed by a microprocessor electronic board for interfaces and service systems and a microprocessor board of the atmospheric measurement module;

периферийная электроника, представленная исполнительными функциональными узлами, датчиками, внутренними интерфейсами М-ДЛС;

peripheral electronics, represented by executive functional units, sensors, M-DLS internal interfaces;

вторичный источник электропитания прибора М-ДЛС от бортовой сети в составе автономного роботизированного комплекса;

secondary power supply of the M-DLS device from the on-board network as part of an autonomous robotic complex;

моноблочный корпус, конструктивно обеспечивающий внутреннюю компоновку прибора М-ДЛС, доступ к его внешним интерфейсным электрическим и газовым соединителям, размещение М-ДЛС на его посадочном месте в составе автономного роботизированного комплекса.

a monoblock case, structurally providing the internal layout of the M-DLS device, access to its external interface electrical and gas connectors, placing the M-DLS on its seat as part of an autonomous robotic complex.

Periodic tuning of the optical frequency of the probe radiation generated by the semiconductor diode DFB laser in the range covering the individual vibrational-rotational absorption lines of a given molecule and its isotopologues provides registration of the absorption spectrum of a gas sample in the form of a time dependence of the output signal recorded by a single-channel photodetector of the device.

The M-DLS includes high-resolution IR spectroscopic measuring channels:

каналы диапазона 2,65 мкм для записи спектральных контуров линий поглощения H₂O и изотопологов H₂O;

channels of 2.65 µm range for recording the spectral contours of the absorption lines of H ₂ O and isotopologues of H ₂ O;

каналы диапазона 2,81 мкм для записи спектральных контуров линий поглощения CO₂ и изотопологов CO₂.

2.81 µm channels for recording the spectral contours of CO ₂ absorption lines and CO ₂ isotopologues.

The scanning intervals for individual measurements, provided by the parameters of current modulation of diode DFB lasers, are about 30 GHz with the possibility of their temperature adjustment and covering the full laser tuning range of about 300 GHz. The maximum spectral resolution in these measurements is determined by the width of the DFB laser radiation line and amounts to 1-3 MHz.

Long-term stabilization of the diode laser radiation frequency, which provides the possibility of accumulating and averaging a large number of spectra and thereby significantly improving the signal-to-noise ratio, is carried out due to the constant maintenance of a certain position of the centers of strong CO ₂ absorption lines within the operating intervals of spectral scanning by organizing digital feedback with controllers operating modes of laser modules.

The solution of the inverse problem of reconstructing variations in molecular concentrations and isotopic ratios will be carried out on the basis of the optical absorption data of atmospheric gas samples transmitted to the Earth.

The sensitivity estimate for some measurement channels is presented in Table 1.

The calculated accuracy of determining isotopic ratios is:

D / H <2%, ¹⁸ O / O <2% (H ₂ O); ¹³ C / C ~ 0.3%, ¹⁸ O / ¹⁷ O / O <0.3% (CO ₂ ).

An additional improvement of the sensitivity of spectral measurements by a factor of ~ 3 will be possible by compressing the taken atmospheric sample in the volume of the analytical cell to a pressure of ~ 30 mbar through the gas interface of the joint system for preparing gas samples of the scientific equipment complex (KNA).

The specific characteristics of the M-DLS device are:

сверхвысокое спектральное разрешение λ/δλ=10⁸, позволяющее детально разрешать форм-фактор регистрируемых линий молекулярного поглощения;

ultra-high spectral resolution λ / δλ = 10 ⁸ , which allows detailed resolution of the form factor of the registered molecular absorption lines;

высокая чувствительность детектирования газов при малых концентрациях, достигаемая за счет оптического накопления заведомо слабого полезного сигнала в атмосферных измерительных каналах при большом числе эффективных полных проходов зондирующего луча через аналитический объем оптической кюветы прибора, что позволяет увеличить эффективный оптический путь до 1000 м при физических размерах прибора менее 0,3 м;

high sensitivity of detecting gases at low concentrations, achieved due to the optical accumulation of an obviously weak useful signal in atmospheric measuring channels with a large number of effective full passes of the probing beam through the analytical volume of the optical cell of the device, which makes it possible to increase the effective optical path to 1000 m with the physical dimensions of the device less 0.3 m;

гибкость управления комплектом диодных РОС-лазеров - эффективное сочетание излучения нескольких рабочих длин волн, генерируемых лазерными излучателями, и различных каналов измерений. Один и тот же лазер может быть использован для измерений в двух или более спектральных каналах за счет подстройки рабочей температуры лазерного кристалла;

flexible control of a set of diode DFB lasers - an effective combination of radiation of several operating wavelengths generated by laser emitters and various measurement channels. The same laser can be used for measurements in two or more spectral channels by adjusting the operating temperature of the laser crystal;

защита рабочего объема и прецизионных оптических элементов от пыли и прочих загрязнений на всех этапах хранения, старта, перелета, посадки и активных измерений;

protection of the working volume and precision optical elements from dust and other contaminants at all stages of storage, launch, flight, landing and active measurements;

эффективность использования аппаратных ресурсов при совместном использовании газового интерфейса и объединенной системы подготовки газовых проб научной аппаратуры автономного роботизированного комплекса.

the efficiency of using hardware resources when using a gas interface and a combined system for preparing gas samples for scientific equipment of an autonomous robotic complex.

The invention can be used in studies of the planets of the solar system as part of scientific equipment for automatic and manned spacecraft, in solving urgent problems of monitoring natural and man-made environments as part of unmanned aerial vehicles and underwater vehicles, in problems of environmental monitoring, geological prospecting, identification of explosives and toxic substances, control production processes, medical diagnostics, etc.

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Claims (1)

The Martian multichannel diode laser spectrometer "M-DLS" is a device for precision measurement of the chemical and isotopic composition of a dusty atmosphere, consisting of an analytical gas volume based on an optical multi-pass cell, a set of monochromatic diode lasers with distributed feedback with periodic tuning of the optical frequency of the probe radiation in range, covering individual vibrational-rotational absorption lines of a given molecule and its isotopologues, and a photodetector, characterized in that an optical multi-pass cell of a full optical intracavity output is used as an analytical gas volume, which is an optical cavity with a reflection coefficient of mirrors of at least 0.999, both the mirrors are partially permeable, and the number of effective full passes of the probing beam through the analytical gas volume of the optical multi-pass cell, which makes it possible to increase the effective optical the specified optical multi-pass analytical gas cell is used as a reference channel for stabilizing the laser radiation frequency along the selected absorption lines, and the specified reference channel allows for long-term stabilization of the laser radiation frequency , which provides the ability to accumulate and average a large number of spectra to significantly improve the signal-to-noise ratio.

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