The mechanisms of $CH_4$ uptake into and release from the ocean are not well understood due mainly to complexity of the biogeochemical cycle and to lack of regional-scale and/or process-scale observations in the marine boundary layers. Without complete understanding of oceanic mechanisms to control the carbon balance and cycles on a various spatial and temporal scales, however, it is difficult to predict future perturbation of oceanic carbon levels and its influence on the global and regional climates. High frequency, high precision continuous measurements for carbon isotopic compositions from dissolved $CH_4$ in the surface ocean and marine atmosphere can provide additional information about the flux pathways and production/consumption processes occurring in the boundary of two large reservoirs. This paper introduces recent advances on optical instruments for real time $CH_4$ isotope analysis to diagnose potential applications for in situ, continuous measurements of carbon isotopic composition of dissolved $CH_4$. Commercially available, three laser absorption spectrometers - quantum cascade laser spectroscopy (QCLAS), off-axis integrated cavity output spectrometer (OA-ICOS), and cavity ring-down spectrometer (CRDS) are discussed in comparison with the conventional isotope ratio mass spectrometry (IRMS). Details of functioning and performance of a CRDS isotope instrument for atmospheric ${\delta}^{13}C-CH_4$ are also given, showing its capability to detect localized methane emission sources.

1 심정희, "해조양식장 수질환경 모니터링을 통한 이산화탄소 단순 수지모델" 한국해양학회 17 (17): 243-251, 2012

2 Wang, Y., "Variations of $O_3$ and CO in summertime at a rural site near Beijing" 8 : 6355-6363, 2008

3 M. Becker, "Using cavity ringdown spectroscopy for continuous monitoring of δ 13 C(CO 2 ) and ƒCO 2 in the surface ocean" Wiley 10 (10): 752-766, 2012

4 Gernot Friedrichs, "Toward continuous monitoring of seawater 13 CO 2 / 12 CO 2 isotope ratio and p CO 2 : Performance of cavity ringdown spectroscopy and gas matrix effects" Wiley 8 (8): 539-551, 2010

5 Paul Quay, "The isotopic composition of atmospheric methane" American Geophysical Union (AGU) 13 (13): 445-461, 1999

6 Arne Körtzinger, "The international at-sea intercomparison of fCO2 systems during the R/V Meteor Cruise 36/1 in the North Atlantic Ocean" Elsevier BV 72 (72): 171-192, 2000

7 L.S. Rothman, "The HITRAN molecular spectroscopic database: edition of 2000 including updates through 2001" Elsevier BV 82 (82): 5-44, 2003

8 H.W. Bange, "The Aegean Sea as a source of atmospheric nitrous oxide and methane" Elsevier BV 53 (53): 41-49, 1996

9 A. Stohl, "Technical note: The Lagrangian particle dispersion model FLEXPART version 6.2" Copernicus GmbH 5 (5): 2461-2474, 2005

10 Weiss, R.F., "Surface water and atmospheric carbon dioxide and nitrous oxide observations by shipboard automated gas chromatography: Results from expeditions between 1977 and 1990. SIO 92-11"

11 Allan, D.W., "Statistics of atomic frequency standards" 54 : 221-230, 1966

12 Stanley C. Tyler, "Stable isotope ratios in atmospheric CH 4 : Implications for seasonal sources and sinks" American Geophysical Union (AGU) 112 (112): 2007

13 Eric R. Crosson, "Stable Isotope Ratios Using Cavity Ring-Down Spectroscopy:  Determination of 13 C/ 12 C for Carbon Dioxide in Human Breath" American Chemical Society (ACS) 74 (74): 2003-2007, 2002

14 Fuu Ming Kai, "Reduced methane growth rate explained by decreased Northern Hemisphere microbial sources" Springer Nature 476 (476): 194-197, 2011

15 S. Eyer, "Real-time analysis of <i>δ</i>¹³C- and <i>δ</i>D-CH₄ in ambient air with laser spectroscopy: method development and first intercomparison results" Copernicus GmbH 9 (9): 263-280, 2016

16 David M. Karl, "Production and transport of methane in oceanic particulate organic matter" Springer Nature 368 (368): 732-734, 1994

17 Philippe Ciais, "Partitioning of ocean and land uptake of CO 2 as inferred by δ 13 C measurements from the NOAA Climate Monitoring and Diagnostics Laboratory Global Air Sampling Network" American Geophysical Union (AGU) 100 (100): 5051-, 1995

18 Marie A. de Angelis, "Methane production during zooplankton grazing on marine phytoplankton" Wiley 39 (39): 1298-1308, 1994

19 Jack J. Middelburg, "Methane distribution in European tidal estuaries" Springer Nature 59 (59): 95-119, 2002

20 A. A. Kosterev, "Methane concentration and isotopic composition measurements with a mid-infrared quantum-cascade laser" The Optical Society 24 (24): 1762-, 1999

21 T. S. Rhee, "Methane and nitrous oxide emissions from the ocean: A reassessment using basin-wide observations in the Atlantic" American Geophysical Union (AGU) 114 (114): 2009

22 Benjamin R. Miller, "Medusa:  A Sample Preconcentration and GC/MS Detector System for in Situ Measurements of Atmospheric Trace Halocarbons, Hydrocarbons, and Sulfur Compounds" American Chemical Society (ACS) 80 (80): 1536-1545, 2008

23 Gregory W. Santoni, "Mass fluxes and isofluxes of methane (CH 4 ) at a New Hampshire fen measured by a continuous wave quantum cascade laser spectrometer" American Geophysical Union (AGU) 117 (117): 2012

24 Daniel J. Repeta, "Marine methane paradox explained by bacterial degradation of dissolved organic matter" Springer Nature 9 (9): 884-887, 2016

25 C. W. Rella, "Local- and regional-scale measurements of CH₄, δ¹³CH₄, and C₂H₆ in the Uintah Basin using a mobile stable isotope analyzer" Copernicus GmbH 8 (8): 4539-4559, 2015

26 P. Bergamaschi, "Isotope analysis based source identification for atmospheric CH 4 and CO sampled across Russia using the Trans-Siberian railroad" American Geophysical Union (AGU) 103 (103): 8227-8235, 1998

27 Zahniser, M.S., "Infrared QC laser applications to field measurements of atmospheric trace gas sources and sinks in environmental research: Enhanced capabilities using continuous wave QCLs" 7222 : 7222OH:1-7222OH:9, 2009

28 A. L. Rice, "High-Precision Continuous-Flow Measurement of δ 13 C and δD of Atmospheric CH 4" American Chemical Society (ACS) 73 (73): 4104-4110, 2001

29 M. F. Witinski, "High precision methane isotopologue ratio measurements at ambient mixing ratios using integrated cavity output spectroscopy" Springer Nature 102 (102): 375-380, 2011

30 B. Tuzson, "High precision and continuous field measurements of δ 13C and δ 18O in carbon dioxide with a cryogen-free QCLAS" Springer Nature 92 (92): 451-458, 2008

31 Wofsy, S.C., "HIAPER Pole-to-Pole Observations (HIPPO): fine-grained, global-scale measurements of climatically important atmospheric gases and aerosols" 369 : 2073-2086, 2011

32 James E. Johnson, "Evaluation of a seawater equilibrator for shipboard analysis of dissolved oceanic trace gases" Elsevier BV 395 (395): 119-132, 1999

33 T. J. Griffis, "Direct measurement of biosphere-atmosphere isotopic CO 2 exchange using the eddy covariance technique" American Geophysical Union (AGU) 113 (113): 2008

34 John B. Miller, "Development of analytical methods and measurements of 13 C/ 12 C in atmospheric CH 4 from the NOAA Climate Monitoring and Diagnostics Laboratory Global Air Sampling Network" American Geophysical Union (AGU) 107 (107): 2002

35 Helen Waechter, "Determination of N_2O isotopomers with quantum cascade laser based absorption spectroscopy" The Optical Society 16 (16): 9239-, 2008

36 David R. Bowling, "Critical evaluation of micrometeorological methods for measuring ecosystem–atmosphere isotopic exchange of CO2" Elsevier BV 116 (116): 159-179, 2003

37 Brass, M., "Continuous-flow isotope ratio mass spectrometry method for carbon and hydrogen isotope measurements on atmospheric methane" 3 : 1707-1721, 2010

38 B. Tuzson, "Continuous isotopic composition measurements of tropospheric CO₂ at Jungfraujoch (3580 m a.s.l.), Switzerland: real-time observation of regional pollution events" Copernicus GmbH 11 (11): 1685-1696, 2011

39 Michael Whiticar, "Constraining past global tropospheric methane budgets with carbon and hydrogen isotope ratios in ice" The Royal Society 365 (365): 1793-1828, 2007

40 IPCC., "Changes in atmospheric constituents and in radiative forcing, in Climate Change 2007. The physical Basis. Contribution of working Group I to the Fourth Assessment Report of the Intergovernmental Panel on Climate Change" Cambridge Univ. Press 129-234, 2007

41 E. A. Kort, "Atmospheric observations of Arctic Ocean methane emissions up to 82° north" Springer Nature 5 (5): 318-321, 2012

42 Ed H. Wahl, "Applications of cavity ring-down spectroscopy to high precision isotope ratio measurement of 13 C/ 12 C in carbon dioxide" Informa UK Limited 42 (42): 21-35, 2006

43 J. Barry McManus, "Application of quantum cascade lasers to high-precision atmospheric trace gas measurements" SPIE-Intl Soc Optical Eng 49 (49): 111124-, 2010

44 A. Voulgarakis, "Analysis of present day and future OH and methane lifetime in the ACCMIP simulations" Copernicus GmbH 13 (13): 2563-2587, 2013

45 David M. Karl, "Aerobic production of methane in the sea" Springer Nature 1 (1): 473-478, 2008

46 P. Werle, "Accuracy and precision of laser spectrometers for trace gas sensing in the presence of optical fringes and atmospheric turbulence" Springer Nature 102 (102): 313-329, 2011

47 Lisa R. Welp, "A meta-analysis of water vapor deuterium-excess in the midlatitude atmospheric surface layer" American Geophysical Union (AGU) 26 (26): 2012

48 J. Mohn, "A liquid nitrogen-free preconcentration unit for measurements of ambient N₂O isotopomers by QCLAS" Copernicus GmbH 3 (3): 609-618, 2010

49 J. B. McManus, "A high precision pulsed quantum cascade laser spectrometer for measurements of stable isotopes of carbon dioxide" Informa UK Limited 52 (52): 2309-2321, 2006

50 V. V. Petrenko, "14CH4 Measurements in Greenland Ice: Investigating Last Glacial Termination CH4 Sources" American Association for the Advancement of Science (AAAS) 324 (324): 506-508, 2009