A new frontier in CO2 flux measurements using a highly portable DIAL laser system
Language
English
Obiettivo Specifico
6V. Pericolosità vulcanica e contributi alla stima del rischio
Status
Published
JCR Journal
JCR Journal
Peer review journal
Yes
Journal
Issue/vol(year)
/6(2016)
Publisher
Nature P.G.
Pages (printed)
33834
Date Issued
September 22, 2016
Subjects
the CO2DIAL is able to measure integrated CO2 path-amounts at distances up to 2000 m using virtually any solid surface as a reflector, whilst also being highly portable.
Abstract
Volcanic CO2 emissions play a key role in the geological carbon cycle, and monitoring of volcanic CO2 fluxes helps to forecast eruptions. The quantification of CO2 fluxes is challenging due to rapid dilution of magmatic CO2 in CO2-rich ambient air and the diffuse nature of many emissions, leading to large uncertainties in the global magmatic CO2 flux inventory. Here, we report measurements using a new DIAL laser remote sensing system for volcanic CO2 (CO2DIAL). Two sites in the volcanic zone of Campi Flegrei (Italy) were scanned, yielding CO2 path-amount profiles used to compute fluxes. Our results reveal a relatively high CO2 flux from Campi Flegrei, consistent with an increasing trend. Unlike previous methods, the CO2DIAL is able to measure integrated CO2 path-amounts at distances up to 2000 m using virtually any solid surface as a reflector, whilst also being highly portable. This opens a new frontier in quantification of geological and anthropogenic CO2 fluxes.
References
1. Berner, R. A. A model for atmospheric CO2 over Phanerozoic time. Am. J. Sci. 291, 339–376, doi: 10.2475/ajs.291.4.339 (1991).
2. Zeebe, R. E. & Caldeira, K. Close mass balance of long-term carbon fluxes from ice-core CO2 and ocean chemistry records. Nature
Geosci. 1, 312–315 (2008).
3. Liu, Z., Dreybrodt, W. & Liu, H. Atmospheric CO2 sink: Silicate weathering or carbonate weathering? Appl. Geochem. 26, 292–294
(2011).
4. Burton, M., G. Sawyer, G. & Granieri, D. Deep carbon emissions from volcanoes. Rev. Mineral. Geochem. 75, 323–354 (2013).
5. IPCC. Climate Change 2013: The Physical Science Basis. Contribution of Working Group I to the Fifth Assessment Report of the
Intergovernmental Panel on Climate Change [Stocker, T. F., Qin, D., Plattner, G.-K., Tignor, M., Allen, S. K., Boschung, J., Nauels, A.,
Xia, Y., Bex, V. & Midgley, P. M. (eds)]. Cambridge University Press, Cambridge, United Kingdom and New York, NY, USA, 1535 pp,
doi: 10.1017/CBO9781107415324 (2013).
6. Lee, H. et al. Massive and prolonged deep carbon emissions associated with continental rifting. Nature Geosci. 9, 145–149 (2016).
7. Kelemen, P. B. & Manning, C. E. Reevaluating carbon fluxes in subduction zones, what goes down, mostly comes up. PNAS 112,
3998–4006, doi: 10.1073/pnas.1507889112 (2015).
8. Gerlach, T. M. et al. Application of the LI-COR CO2 analyzer to volcanic plumes: A case study, volcán Popocatépetl, Mexico, June 7
and 10, 1995. J. Geophys. Res. 102, 8005–8019 (1997).
9. Carapezza, M. L., Inguaggiato, S., Brusca, L. & Longo, M. Geochemical precursors of the activity of an open-conduit volcano: The
Stromboli 2002–2003 eruptive events. Geophys. Res. Lett. 31, L07620 (2004).
10. Aiuppa, G. et al. First observational evidence for the CO2-driven origin of Stromboli’s major explosions. Solid Earth 2, 135–142
(2011).
11. Poland, M. P., Miklius, A., Sutton, J. & Thornber, C. R. A mantle-driven surge in magma supply to Kīlauea Volcano during
2003–2007, Nature Geosci. 5, 295–300 (2012).
12. Shinohara, H. A new technique to estimate volcanic gas composition: plume measurements with a portable multi-sensor system. J.
Volcanol. Geotherm. Res. 143, 319–333 (2005).
13. Allard, P. et al. Eruptive and diffuse emissions of CO2 from Mount Etna, Nature 351, 387–391 (1991).
14. Symonds, R. B., Reed, M. H. & Rose, W. I. Origin, speciation, and fluxes of trace-element gases at Augustine volcano, Alaska – Insights
into magma degassing and fumarolic processes. Geochim. Cosmochim. Acta 56, 633–657, doi: 10.1016/0016-7037(92)90087-Y (1992).
15. Gerlach, T. M., McGee, K. A., Sutton, A. J. & Elias, T. Rates of volcanic CO2 degassing from airborne determinations of SO2 Emission
rates and plume CO2/SO2: test study at Pu′ u ′ O′ o Cone, Kilauea Volcano, Hawaii. Geophys. Res. Lett. 25, 2675 - 2678 (1998).
16. Shinohara, H., Kazahaya, K., Saito, G., Fukui, K. & Odai, M. Variation of CO2/SO2 ratio in volcanic plumes of Miyakejima: Stable
degassing deduced from heliborne measurements. Geophys. Res. Lett. 30, 1208, doi: 10.1029/2002GL016105 (2003).
17. Allard, P., Burton, M. & Muré, P. Spectroscopic evidence for a lava fountain driven by previously accumulated magmatic gas, Nature
433, 407–410 (2005).
18. Burton, M., Allard, P., Muré, F. & La Spina, A. Magmatic gas composition reveals the source depth of slug-driven Strombolian
explosive activity, Science 317, 227–230 (2007).
19. Galle B., Oppenheimer C., Geyer A., McGonigle A. & Edmonds M. A miniaturised ultraviolet spectrometer for remote sensing of
SO2 fluxes: a new tool for volcano surveillance. J. Volcanol. Geotherm. Res. 119, 241–254 (2002).
20. Fischer, T. et al. The 2005 and 2006 eruptions of Ol Doinyo Lengai: assessing deep and shallow processes at an active carbonatite
volcano using volatile chemistry and fluxes. Eos Trans. AGU 87, Fall Meet. Suppl., Abstract V14B-04 (2006).
21. Wardell, L. J., Kyle, P. R. & Chaffin, C. Carbon dioxide and carbon monoxide emission rates from an alkaline intra-plate volcano: Mt.
Erebus, Antarctica. J. Volcanol. Geotherm. Res. 131, 109–121 (2004).
22. Diaz, J. A. et al. Utilization of in situ airborne MS-based instrumentation for the study of gaseous emissions at active volcanoes. Int.
J. Mass. Spectrom. 295, 105–112 (2010).
23. Lewicki, J. et al. Comparative soil CO2 flux measurement and geostatistical estimation methods on Masaya volcano, Nicaragua. Bull.
Volc. 68, 76–90 (2005).
24. Granieri, D. et al. Atmospheric dispersion of natural carbon dioxide emissions on Vulcano Island, Italy. J. Geophys. Res. Solid Earth
119, 5398–5413 (2014).
25. d’Alessandro, W. D. et al. Diffuse and focused carbon dioxide and methane emissions from the Sousaki geothermal system, Greece.
Geophys. Res. Lett. 33, L05307 (2006).
26. Aiuppa, A. et al. First observations of the fumarolic gas output from a restless caldera: Implications for the current period of unrest
(2005–2013) at Campi Flegrei. Geochem. Geophys. Geosyst. 14, 4153–4169 (2013).
27. Werner, C., Wyngaard, J. C. & Brantley, S. L. Eddy-Correlation Measurement of Hydrothermal Gases, Geophys. Res. Lett. 27,
2925–2928 (2000).
28. Werner, C., Chiodini, G., Voigt, D. E. & Brantley, S. L. Monitoring volcanic hazard using eddy covariance at Solfatara volcano,
Naples, Italy, Earth Planet. Sci. Lett. 210, 561–577 (2003).
29. Chiodini, G., Cioni, R., Giudi, M., Raco, B. & Marini, L. Soil CO2 flux measurements in volcanic and geothermal areas. Appl.
Geochem. 13, 543–552 (1998).
30. Hards, V. L. Volcanic contributions to the global carbon cycle. British Geological Survey Occasional Report No. 10, 26pp. (2005).
31. Cardellini, C. et al. Accumulation chamber measurements of methane fluxes: application to volcanic-geothermal areas and landfills.
Appl. Geochem. 18, 45–54 (2003).
32. Aiuppa, A. et al. Rates of carbon dioxide plume degassing from Mount Etna volcano. J. Geophys. Res. 111, B09207 (2006).
33. Naughton J. J., Derby, J. V. & Glover, R. B. Infrared measurements on volcanic gas and fume: Kilauea eruption, 1968. J. Geophys. Res.
74, 3273–3277 (1969).
34. Burton, M. R., Oppenheimer, C., Horrocks, L. A. & Francis, P. W. Remote sensing of CO2 and H2O emission rates from Masaya
volcano, Nicaragua. Geology 28, 915–918 (2000).
35. La Spina, A. et al. New insights into volcanic processes at Stromboli from Cerberus, a remote-controlled open-path FTIR scanner. J.
Volcanol. Geotherm. Res. 249, 66–76 (2013).
36. Chen, H. S. Space Remote Sensing Systems – An Introduction. Academic Press Inc., Orlando, Florida, USA (1985).
37. Spinetti C., Carrere, V., Buongiorno, M. F., Sutton, A. J. & Elias, T. Carbon dioxide of Pu’u’O’ o volcanic plume at Kilauea retrieved
by AVIRIS hyperspectral data. Remote Sens. Environ. 112, 3192–3199 (2008).
38. Platt, U. Differental optical absorption spectroscopy (DOAS). Chem. Anal. Series 127, 27–83 (1994).
39. Weibring, P. et al. Monitoring of volcanic sulphur dioxide emissions using differential absorption lidar (DIAL), differential optical
absorption spectroscopy (DOAS), and correlation spectroscopy (COSPEC). Appl. Phys. B 67, 419–426 (1998).
40. Kern, C. et al. Improving the accuracy of SO2 column densities and emission rates obtained from upward-looking UV-spectroscopic
measurements of volcanic plumes by taking realistic radiative transfer into account. J. Geophys. Res. 117, D20302, doi:
10.1029/2012JD017936 (2012).
41. Menzies, R. T. & Chahine, M. T. Remote Atmospheric Sensing with an Airborne Laser Absorption Spectrometer. Appl. Opt. 13,
2840–2849 (1974).
42. Pedone, M. et al. Volcanic CO2 flux measurement at Campi Flegrei by Tunable Diode Laser absorption Spectroscopy. Bull. Volc. 76,
doi: 10.1007/s00445-014-0812-z (2014).
43. Carapezza, M. et al. Measurement of volcanic SO2 in the atmosphere by DIAL remote sensing techniques. in Man and His
Ecosystem, edited by Brasser, L. J. & Mulder, W. C. pp. 77–82, Elsevier, New York (1989).
44. Edner, H. et al. Total Fluxes of Sulfur Dioxide from the Italian Volcanoes Etna, Stromboli and Vulcano Measured by Differential
Absorption LIDAR and Passive Differential Optical Absorption Spectroscopy. J. Geophys. Res. 99, 827–838 (1994).
45. Gibert, F., Flamant, P. H., Bruneau, D. & Loth, C. Two- micrometer heterodyne differential absorption lidar measurements of the
atmospheric CO2 concentration in the boundary layer. Appl. Opt. 47, 944–956 (2008).
46. Amediek, A., Fix, A., Wirth, M. & Ehret, G. Development of an OPO system at 1.57 μ m for integrated path DIAL measurement of
atmospheric carbon dioxide. Appl. Phys. B 92, 295–302 (2008).
47. Abshire, J. B. et al. Pulsed airborne lidar measurements of atmospheric CO2 column absorption. Tellus B 62B, 770–783 (2010).
48. Sakaizawa, D. et al. An airborne amplitude-modulated 1.57 μ m differential laser absorption spectrometer: simultaneous
measurement of partial column-averaged dry air concentration of CO2 and target range. Atmos. Meas. Tech. 6, 387–396 (2013).
49. Robinson, R. A. et al. First measurements of a carbon dioxide plume from an industrial source using a ground based mobile
differential absorption lidar. Environ. Sci.: Processes Impacts 16, 1957–1966 (2014).
50. Aiuppa, A. et al. New ground-based lidar enables volcanic CO2 flux measurements. Sci. Rep. 5, 13614; doi: 10.1038/srep13614
(2015).
51. Orsi, G., D’ Antonio, M., de Vita, S. & Gallo, G. The Neapolitan yellow tuff, a large-magnitude trachytic phreatoplinian eruption;
eruptive dynamics, magma withdrawal and caldera collapse. J. Volcanol. Geotherm. Res 53, 275 - 287 (1992).
52. Costa, A. et al. Quantifying volcanic ash dispersal and impact of the Campanian Ignimbrite super-eruption. Geophys. Res. Lett. 39,
L10310 (2012).
53. Ricci, T., Barberi, F., Davis, M. S., Isaia, R. & Nave, R. Volcanic risk perception in the Campi Flegrei area. J. Volcanol. Geotherm. Res.
254, 118 - 130 (2013).
54. Chiodini, G. et al. CO2 degassing and energy release at Solfatara volcano, Campi Flegrei, Italy. J. Geophys. Res. 106, 213–221 (2001).
55. d’Auria, L. Update sullo stato dei Campi Flegrei, INGV, Sezione di Napoli, Report, available at: ftp://ftp.ingv.it/pro/web_ingv/
Convegno_Struttura%20_Vulcani/presentazioni/15_D’auria_CampiFlegrei/dauria_cf.pdf, accessed in March 2016 (2015).
56. Granieri, D., Chiodini, G., Marzocchi, W. & Avino, R. Continuous monitoring of CO2 soil diffuse degassing at Phlegraean Fields
(Italy): influence of environmental and volcanic parameters. Earth Planet. Sci. Lett. 212, 167–179 (2003).
57. Chiodini, G. et al. Long-term variations of the Campi Flegrei, Italy, volcanic system as revealed by the monitoring of hydrothermal
activity. J. Geophys. Res. 115, B03205, doi: 10.1029/2008JB006258 (2010).
58. Granieri, D., Costa, A., Macedonio, G., Bisson, M. & Chiodini, G. Carbon dioxide in the urban area of Naples: Contribution and
effects of the volcanic source. J. Volcanol. Geotherm. Res. 260, 52–61 (2013).
59. Tassi, F. et al. Diffuse soil emission of hydrothermal gases (CO2, CH4 and C6H6) at the Solfatara crater (Phlegraean Fields, southern
Italy). Appl. Geochem. 35, 142–153 (2013).
60. Bagnato, E. et al. First combined flux chamber survey of mercury and CO2 emissions from soil diffuse degassing at Solfatara of
Pozzuoli crater, Campi Flegrei (Italy): Mapping and quantification of gas release. J. Volcanol. Geotherm. Res. 289, 26 - 40 (2014).
61. Rothman, L. S. et al. The HITRAN 2012 molecular spectroscopic database. J. Quant. Spectrosc. Radiat. Transfer 130, 4–50 (2013).
62. Student, The probability error of a mean. Biometrika 6, 1–25 (1908).
63. Queißer, M., Burton, M. & Fiorani, L. Differential absorption lidar for volcanic CO2 sensing tested in an unstable atmosphere. Opt.
Express 23, 6634–6644 (2015).
64. MacKerrow, E. P., Schmitt, M. J. & Thompson, D. C. Effect of speckle on lidar pulse–pair ratio statistics. Appl. Optics 36, 8650–8669
(1997).
65. Tarquini, S. et al. TINITALY/01: a new Triangular Irregular Network of Italy. Ann. Geophys. 50, 407–425 http://tinitaly.pi.ingv.it
(2007).
2. Zeebe, R. E. & Caldeira, K. Close mass balance of long-term carbon fluxes from ice-core CO2 and ocean chemistry records. Nature
Geosci. 1, 312–315 (2008).
3. Liu, Z., Dreybrodt, W. & Liu, H. Atmospheric CO2 sink: Silicate weathering or carbonate weathering? Appl. Geochem. 26, 292–294
(2011).
4. Burton, M., G. Sawyer, G. & Granieri, D. Deep carbon emissions from volcanoes. Rev. Mineral. Geochem. 75, 323–354 (2013).
5. IPCC. Climate Change 2013: The Physical Science Basis. Contribution of Working Group I to the Fifth Assessment Report of the
Intergovernmental Panel on Climate Change [Stocker, T. F., Qin, D., Plattner, G.-K., Tignor, M., Allen, S. K., Boschung, J., Nauels, A.,
Xia, Y., Bex, V. & Midgley, P. M. (eds)]. Cambridge University Press, Cambridge, United Kingdom and New York, NY, USA, 1535 pp,
doi: 10.1017/CBO9781107415324 (2013).
6. Lee, H. et al. Massive and prolonged deep carbon emissions associated with continental rifting. Nature Geosci. 9, 145–149 (2016).
7. Kelemen, P. B. & Manning, C. E. Reevaluating carbon fluxes in subduction zones, what goes down, mostly comes up. PNAS 112,
3998–4006, doi: 10.1073/pnas.1507889112 (2015).
8. Gerlach, T. M. et al. Application of the LI-COR CO2 analyzer to volcanic plumes: A case study, volcán Popocatépetl, Mexico, June 7
and 10, 1995. J. Geophys. Res. 102, 8005–8019 (1997).
9. Carapezza, M. L., Inguaggiato, S., Brusca, L. & Longo, M. Geochemical precursors of the activity of an open-conduit volcano: The
Stromboli 2002–2003 eruptive events. Geophys. Res. Lett. 31, L07620 (2004).
10. Aiuppa, G. et al. First observational evidence for the CO2-driven origin of Stromboli’s major explosions. Solid Earth 2, 135–142
(2011).
11. Poland, M. P., Miklius, A., Sutton, J. & Thornber, C. R. A mantle-driven surge in magma supply to Kīlauea Volcano during
2003–2007, Nature Geosci. 5, 295–300 (2012).
12. Shinohara, H. A new technique to estimate volcanic gas composition: plume measurements with a portable multi-sensor system. J.
Volcanol. Geotherm. Res. 143, 319–333 (2005).
13. Allard, P. et al. Eruptive and diffuse emissions of CO2 from Mount Etna, Nature 351, 387–391 (1991).
14. Symonds, R. B., Reed, M. H. & Rose, W. I. Origin, speciation, and fluxes of trace-element gases at Augustine volcano, Alaska – Insights
into magma degassing and fumarolic processes. Geochim. Cosmochim. Acta 56, 633–657, doi: 10.1016/0016-7037(92)90087-Y (1992).
15. Gerlach, T. M., McGee, K. A., Sutton, A. J. & Elias, T. Rates of volcanic CO2 degassing from airborne determinations of SO2 Emission
rates and plume CO2/SO2: test study at Pu′ u ′ O′ o Cone, Kilauea Volcano, Hawaii. Geophys. Res. Lett. 25, 2675 - 2678 (1998).
16. Shinohara, H., Kazahaya, K., Saito, G., Fukui, K. & Odai, M. Variation of CO2/SO2 ratio in volcanic plumes of Miyakejima: Stable
degassing deduced from heliborne measurements. Geophys. Res. Lett. 30, 1208, doi: 10.1029/2002GL016105 (2003).
17. Allard, P., Burton, M. & Muré, P. Spectroscopic evidence for a lava fountain driven by previously accumulated magmatic gas, Nature
433, 407–410 (2005).
18. Burton, M., Allard, P., Muré, F. & La Spina, A. Magmatic gas composition reveals the source depth of slug-driven Strombolian
explosive activity, Science 317, 227–230 (2007).
19. Galle B., Oppenheimer C., Geyer A., McGonigle A. & Edmonds M. A miniaturised ultraviolet spectrometer for remote sensing of
SO2 fluxes: a new tool for volcano surveillance. J. Volcanol. Geotherm. Res. 119, 241–254 (2002).
20. Fischer, T. et al. The 2005 and 2006 eruptions of Ol Doinyo Lengai: assessing deep and shallow processes at an active carbonatite
volcano using volatile chemistry and fluxes. Eos Trans. AGU 87, Fall Meet. Suppl., Abstract V14B-04 (2006).
21. Wardell, L. J., Kyle, P. R. & Chaffin, C. Carbon dioxide and carbon monoxide emission rates from an alkaline intra-plate volcano: Mt.
Erebus, Antarctica. J. Volcanol. Geotherm. Res. 131, 109–121 (2004).
22. Diaz, J. A. et al. Utilization of in situ airborne MS-based instrumentation for the study of gaseous emissions at active volcanoes. Int.
J. Mass. Spectrom. 295, 105–112 (2010).
23. Lewicki, J. et al. Comparative soil CO2 flux measurement and geostatistical estimation methods on Masaya volcano, Nicaragua. Bull.
Volc. 68, 76–90 (2005).
24. Granieri, D. et al. Atmospheric dispersion of natural carbon dioxide emissions on Vulcano Island, Italy. J. Geophys. Res. Solid Earth
119, 5398–5413 (2014).
25. d’Alessandro, W. D. et al. Diffuse and focused carbon dioxide and methane emissions from the Sousaki geothermal system, Greece.
Geophys. Res. Lett. 33, L05307 (2006).
26. Aiuppa, A. et al. First observations of the fumarolic gas output from a restless caldera: Implications for the current period of unrest
(2005–2013) at Campi Flegrei. Geochem. Geophys. Geosyst. 14, 4153–4169 (2013).
27. Werner, C., Wyngaard, J. C. & Brantley, S. L. Eddy-Correlation Measurement of Hydrothermal Gases, Geophys. Res. Lett. 27,
2925–2928 (2000).
28. Werner, C., Chiodini, G., Voigt, D. E. & Brantley, S. L. Monitoring volcanic hazard using eddy covariance at Solfatara volcano,
Naples, Italy, Earth Planet. Sci. Lett. 210, 561–577 (2003).
29. Chiodini, G., Cioni, R., Giudi, M., Raco, B. & Marini, L. Soil CO2 flux measurements in volcanic and geothermal areas. Appl.
Geochem. 13, 543–552 (1998).
30. Hards, V. L. Volcanic contributions to the global carbon cycle. British Geological Survey Occasional Report No. 10, 26pp. (2005).
31. Cardellini, C. et al. Accumulation chamber measurements of methane fluxes: application to volcanic-geothermal areas and landfills.
Appl. Geochem. 18, 45–54 (2003).
32. Aiuppa, A. et al. Rates of carbon dioxide plume degassing from Mount Etna volcano. J. Geophys. Res. 111, B09207 (2006).
33. Naughton J. J., Derby, J. V. & Glover, R. B. Infrared measurements on volcanic gas and fume: Kilauea eruption, 1968. J. Geophys. Res.
74, 3273–3277 (1969).
34. Burton, M. R., Oppenheimer, C., Horrocks, L. A. & Francis, P. W. Remote sensing of CO2 and H2O emission rates from Masaya
volcano, Nicaragua. Geology 28, 915–918 (2000).
35. La Spina, A. et al. New insights into volcanic processes at Stromboli from Cerberus, a remote-controlled open-path FTIR scanner. J.
Volcanol. Geotherm. Res. 249, 66–76 (2013).
36. Chen, H. S. Space Remote Sensing Systems – An Introduction. Academic Press Inc., Orlando, Florida, USA (1985).
37. Spinetti C., Carrere, V., Buongiorno, M. F., Sutton, A. J. & Elias, T. Carbon dioxide of Pu’u’O’ o volcanic plume at Kilauea retrieved
by AVIRIS hyperspectral data. Remote Sens. Environ. 112, 3192–3199 (2008).
38. Platt, U. Differental optical absorption spectroscopy (DOAS). Chem. Anal. Series 127, 27–83 (1994).
39. Weibring, P. et al. Monitoring of volcanic sulphur dioxide emissions using differential absorption lidar (DIAL), differential optical
absorption spectroscopy (DOAS), and correlation spectroscopy (COSPEC). Appl. Phys. B 67, 419–426 (1998).
40. Kern, C. et al. Improving the accuracy of SO2 column densities and emission rates obtained from upward-looking UV-spectroscopic
measurements of volcanic plumes by taking realistic radiative transfer into account. J. Geophys. Res. 117, D20302, doi:
10.1029/2012JD017936 (2012).
41. Menzies, R. T. & Chahine, M. T. Remote Atmospheric Sensing with an Airborne Laser Absorption Spectrometer. Appl. Opt. 13,
2840–2849 (1974).
42. Pedone, M. et al. Volcanic CO2 flux measurement at Campi Flegrei by Tunable Diode Laser absorption Spectroscopy. Bull. Volc. 76,
doi: 10.1007/s00445-014-0812-z (2014).
43. Carapezza, M. et al. Measurement of volcanic SO2 in the atmosphere by DIAL remote sensing techniques. in Man and His
Ecosystem, edited by Brasser, L. J. & Mulder, W. C. pp. 77–82, Elsevier, New York (1989).
44. Edner, H. et al. Total Fluxes of Sulfur Dioxide from the Italian Volcanoes Etna, Stromboli and Vulcano Measured by Differential
Absorption LIDAR and Passive Differential Optical Absorption Spectroscopy. J. Geophys. Res. 99, 827–838 (1994).
45. Gibert, F., Flamant, P. H., Bruneau, D. & Loth, C. Two- micrometer heterodyne differential absorption lidar measurements of the
atmospheric CO2 concentration in the boundary layer. Appl. Opt. 47, 944–956 (2008).
46. Amediek, A., Fix, A., Wirth, M. & Ehret, G. Development of an OPO system at 1.57 μ m for integrated path DIAL measurement of
atmospheric carbon dioxide. Appl. Phys. B 92, 295–302 (2008).
47. Abshire, J. B. et al. Pulsed airborne lidar measurements of atmospheric CO2 column absorption. Tellus B 62B, 770–783 (2010).
48. Sakaizawa, D. et al. An airborne amplitude-modulated 1.57 μ m differential laser absorption spectrometer: simultaneous
measurement of partial column-averaged dry air concentration of CO2 and target range. Atmos. Meas. Tech. 6, 387–396 (2013).
49. Robinson, R. A. et al. First measurements of a carbon dioxide plume from an industrial source using a ground based mobile
differential absorption lidar. Environ. Sci.: Processes Impacts 16, 1957–1966 (2014).
50. Aiuppa, A. et al. New ground-based lidar enables volcanic CO2 flux measurements. Sci. Rep. 5, 13614; doi: 10.1038/srep13614
(2015).
51. Orsi, G., D’ Antonio, M., de Vita, S. & Gallo, G. The Neapolitan yellow tuff, a large-magnitude trachytic phreatoplinian eruption;
eruptive dynamics, magma withdrawal and caldera collapse. J. Volcanol. Geotherm. Res 53, 275 - 287 (1992).
52. Costa, A. et al. Quantifying volcanic ash dispersal and impact of the Campanian Ignimbrite super-eruption. Geophys. Res. Lett. 39,
L10310 (2012).
53. Ricci, T., Barberi, F., Davis, M. S., Isaia, R. & Nave, R. Volcanic risk perception in the Campi Flegrei area. J. Volcanol. Geotherm. Res.
254, 118 - 130 (2013).
54. Chiodini, G. et al. CO2 degassing and energy release at Solfatara volcano, Campi Flegrei, Italy. J. Geophys. Res. 106, 213–221 (2001).
55. d’Auria, L. Update sullo stato dei Campi Flegrei, INGV, Sezione di Napoli, Report, available at: ftp://ftp.ingv.it/pro/web_ingv/
Convegno_Struttura%20_Vulcani/presentazioni/15_D’auria_CampiFlegrei/dauria_cf.pdf, accessed in March 2016 (2015).
56. Granieri, D., Chiodini, G., Marzocchi, W. & Avino, R. Continuous monitoring of CO2 soil diffuse degassing at Phlegraean Fields
(Italy): influence of environmental and volcanic parameters. Earth Planet. Sci. Lett. 212, 167–179 (2003).
57. Chiodini, G. et al. Long-term variations of the Campi Flegrei, Italy, volcanic system as revealed by the monitoring of hydrothermal
activity. J. Geophys. Res. 115, B03205, doi: 10.1029/2008JB006258 (2010).
58. Granieri, D., Costa, A., Macedonio, G., Bisson, M. & Chiodini, G. Carbon dioxide in the urban area of Naples: Contribution and
effects of the volcanic source. J. Volcanol. Geotherm. Res. 260, 52–61 (2013).
59. Tassi, F. et al. Diffuse soil emission of hydrothermal gases (CO2, CH4 and C6H6) at the Solfatara crater (Phlegraean Fields, southern
Italy). Appl. Geochem. 35, 142–153 (2013).
60. Bagnato, E. et al. First combined flux chamber survey of mercury and CO2 emissions from soil diffuse degassing at Solfatara of
Pozzuoli crater, Campi Flegrei (Italy): Mapping and quantification of gas release. J. Volcanol. Geotherm. Res. 289, 26 - 40 (2014).
61. Rothman, L. S. et al. The HITRAN 2012 molecular spectroscopic database. J. Quant. Spectrosc. Radiat. Transfer 130, 4–50 (2013).
62. Student, The probability error of a mean. Biometrika 6, 1–25 (1908).
63. Queißer, M., Burton, M. & Fiorani, L. Differential absorption lidar for volcanic CO2 sensing tested in an unstable atmosphere. Opt.
Express 23, 6634–6644 (2015).
64. MacKerrow, E. P., Schmitt, M. J. & Thompson, D. C. Effect of speckle on lidar pulse–pair ratio statistics. Appl. Optics 36, 8650–8669
(1997).
65. Tarquini, S. et al. TINITALY/01: a new Triangular Irregular Network of Italy. Ann. Geophys. 50, 407–425 http://tinitaly.pi.ingv.it
(2007).
Type
article
File(s)![Thumbnail Image]()
Loading...
Name
2016_Solfatara_DIAL.pdf
Size
1.33 MB
Format
Adobe PDF
Checksum (MD5)
055bb3f54121c1b0726c9e3837f21fac