초록 ▼

Gas having stable isotopes is monitored continuously by using a system that sends a modulated laser beam to the gas and collects and transmits the light not absorbed by the gas to a detector. Gas from geological storage, or from the atmosphere can be monitored continuously without collecting samples

Gas having stable isotopes is monitored continuously by using a system that sends a modulated laser beam to the gas and collects and transmits the light not absorbed by the gas to a detector. Gas from geological storage, or from the atmosphere can be monitored continuously without collecting samples and transporting them to a lab.

대표청구항 ▼

1. A system for monitoring stable isotopes from a sample of gas comprising: a cell for receiving a sample of gas,a pump for sending the sample of gas into the cell,a tunable diode laser for providing a laser beam having an original carrier frequency (ωc),a modulation source operating in the radiofre

1. A system for monitoring stable isotopes from a sample of gas comprising: a cell for receiving a sample of gas,a pump for sending the sample of gas into the cell,a tunable diode laser for providing a laser beam having an original carrier frequency (ωc),a modulation source operating in the radiofrequency regime for modulating the original carrier frequency (ωc) of the laser beam from the tunable diode laser, thereby producing a modulated laser beam having the original carrier frequency (ωc) and sidebands on either side of and evenly spaced apart from the carrier frequency by a modulation frequency (ωm), the modulated laser beam directed at a sample of gas inside the cell,a detector for providing a detection signal from a stable isotope from the gas sample inside the cell, said detector comprising a reference channel and a signal channel,an amplifier for amplifying the detection signal from said detector,an optical fiber for transmitting light from the multipass cell to the signal channel of said detector,a focusing means for focusing light from the cell into the optical fiber,a beamsplitter for directing the modulated laser beam simultaneously to the cell and to the reference channel of the detector, anda polarizer for adjusting fractions of modulated laser light directed to the cell and the reference channel of the detector via the beamsplitter,wherein the system lacks a reference cell and is configured such that said beamsplitter splits the modulated laser beam into a reference beam and a signal beam, wherein said reference beam is sent directly to the reference channel of the detector and said signal beam is sent to said cell containing a sample of gas and afterward to the signal channel of the detector. 2. The system of claim 1, wherein said cell for receiving a gas sample is a multipass cell. 3. The system of claim 1, wherein said modulation source is capable of direct laser modulation. 4. The system of claim 1, wherein said modulation source comprises an electro optical phase modulator. 5. A method for continuously monitoring a gas comprising stable isotopes, comprising: pumping a first sample of gas having stable isotopes into a cell,splitting a frequency modulated laser beam into a reference beam and a signal beam,directing the reference beam directly to a reference channel of a detector while simultaneously directing the signal beam to a cell containing the first sample of a gas having stable isotopes, the gas interacting with the signal beam and producing a first light emission from the interaction,transmitting the first light emission through an optical fiber to a signal channel of the detector,replacing the first sample of the gas with a second sample of a gas pumped into the cell, the second sample of gas producing a second light emission,transmitting the second light emission through the optical fiber to the signal channel of the detector,comparing the first light emission with the second light emission, thereby continuously monitoring the gas. 6. The method of claim 5, wherein the first and second samples of the gas are taken from approximately the same location so that changes in gas composition from that location are monitored as time passes. 7. The method of claim 6, further comprising repeating the steps of the method at a different location so that changes in gas composition at different locations are monitored and may be compared as time passes. 8. The method of claim 5, wherein the gas is CO2. 9. A spectroscopic system for regional monitoring of atmospheric gas comprising: a tunable diode laser for providing a laser beam having an original carrier frequency (ωc),a modulation source operating in the radiofrequency regime for modulating the original carrier frequency (ωc) of the laser beam from the tunable diode laser, thereby producing a modulated laser beam having the original carrier frequency (ωc) and sidebands on either side of and evenly spaced apart from the carrier frequency by a modulation frequency (ωm), the modulated laser beam directed at a sample of gas,a detector for providing a detection signal from a stable isotope from a gas sample comprising stable isotopes, said detector comprising a reference channel and a signal channel,an amplifier for amplifying the detection signal from said detector,an optical fiber for transmitting light from the gas sample to the signal channel of said detector,a focusing means for focusing light emitted from the gaseous sample into the optical fiber,a beamsplitter for splitting the modulated laser beam into a reference beam and a signal beam, the system lacking a reference cell and configured such that the reference beam is sent directly to the reference channel of the detector and the signal beam is sent to a beam expander,a beam expander for controlling beam divergence as the signal beam probes a remote sample of gas,an airplane comprising an airplane wing having a mirror thereon for reflecting the light from the remote sample of gas as the airplane flies over a region of interest,a collection lens for receiving the light reflected from the mirror on the airplane wing,wherein said optical fiber transmits the collected light from the collection lens to the signal channel of said detector. 10. A method for continuously monitoring CO2, comprising: (a) splitting a frequency modulated laser beam from a tunable diode laser into a reference beam and a signal beam and simultaneously sending the signal beam to gas remote from the detector while sending the reference beam directly to a reference channel of the detector, the gas comprising CO2 that interacts with the modulated laser beam, whereby the gas absorbs energy from the signal beam,(b) collecting the light not absorbed by the gas and(c) transmitting the collected light through an optical fiber to a signal channel of the detector,(d) analyzing the light transmission to provide a first 13C/12C ratio,(e) repeating steps (a), (b), (c), and (d) at a later time, thereby providing a second 13C/12C ratio, and(f) comparing first 13C/12C ratio with the second 13C/12C ratio, thereby monitoring CO2 remotely in-situ as time passes. 11. The method of claim 10, wherein the sample of gas is from underground. 12. The method of claim 10, wherein the gas is in the atmosphere. 13. The method of claim 10, wherein the step of collecting the light not absorbed by the gas comprises reflecting collected light from an airborne platform in the atmosphere to a collection lens remote from the atmosphere. 14. The method of claim 10, wherein the modulation source is capable of direct laser modulation. 15. The method of claim 10, wherein the modulation source comprises an electro optical phase modulator.