[1] Wang W, Gao Q, Qin H, et al . The study on greenhouse effect, emission quantification and control of methane [J]. Urban Gas , 2020, (4): 4-9.
[2] Schwietzke S, Sherwood O A, Bruhwiler L M P, et al . Upward revision of global fossil fuel methane emissions based on isotope database [J]. Nature , 2016, 538(7623): 88-91.
[3] Zhang Y Z, Gautam R, Pandey S, et al . Quantifying methane emissions from the largest oil-producing basin in the United States from space [J]. Science Advances , 2020, 6(17): eaaz5120.
[5] Jacob D J, Turner A J, Maasakkers J D, et al . Satellite observations of atmospheric methane and their value for quantifying methane emissions [J]. Atmospheric Chemistry and Physics , 2016, 16(22): 14371-14396.
[6] Kuze A, Suto H, Nakajima M, et al . Thermal and near infrared sensor for carbon observation Fourier-transform spectrometer on the Greenhouse Gases Observing Satellite for greenhouse gases monitoring [J]. Applied Optics , 2009, 48(35): 6716-6733.
[7] de Gouw J A, Veefkind J P, Roosenbrand E, et al . Daily satellite observations of methane from oil and gas production regions in the United States [J]. Scientific Reports , 2020, 10(1): 1379.
[8] Liu L Y, Chen L F, Liu Y, et al . Satellite remote sensing for global stocktaking: Methods, progress and perspectives [J]. National Remote Sensing Bulletin , 2022, 26(2): 243-267.
[9] Bradley E S, Leifer I, Roberts D A, et al . Detection of marine methane emissions with AVIRIS band ratios [J]. Geophysical Research Letters , 2011, 38(10): L10702.
[10] Thorpe A K, Roberts D A, Bradley E S, et al . High resolution mapping of methane emissions from marine and terrestrial sources using a cluster-tuned matched filter technique and imaging spectrometry [J]. Remote Sensing of Environment , 2013, 134: 305-318.
[11] Thorpe A K, Frankenberg C, Aubrey A D, et al . Mapping methane concentrations from a controlled release experiment using the next generation airborne visible/infrared imaging spectrometer (AVIRIS-NG) [J]. Remote Sensing of Environment , 2016, 179: 104-115.
[12] Guanter L, Irakulis-Loitxate I, Gorroo J, et al . Mapping methane point emissions with the PRISMA spaceborne imaging spectrometer [J]. Remote Sensing of Environment , 2021, 265: 112671.
[13] Varon D J, McKeever J, Jervis D, et al . Satellite discovery of anomalously large methane point sources from oil/gas production [J]. Geophysical Research Letters , 2019, 46(22): 13507-13516.
[14] Frankenberg C, Thorpe A K, Thompson D R, et al . Airborne methane remote measurements reveal heavy-tail flux distribution in Four Corners region [J]. Proceedings of the National Academy of Sciences of the United States of America , 2016, 113(35): 9734-9739.
[15] Yue Q, Zhang G J, Wang Z. Preliminary estimation of methane emission and its distribution in China [J]. Geographical Research , 2012, 31(9): 1559-1570.
[16] Liu Y N, Sun D X, Hu X N, et al . Development of visible and short-wave infrared hyperspectral imager onboard GF-5 satellite [J]. Journal of Remote Sensing , 2020, 24(4): 333-344.
[17] Foote M D, Dennison P E, Thorpe A K, et al . Fast and accurate retrieval of methane concentration from imaging spectrometer data using sparsity prior [J]. IEEE Transactions on Geoscience and Remote Sensing , 2020, 58(9): 6480-6492.
[18] Scafutto R D M, van der Werff H, Bakker W H, et al . An evaluation of airborne SWIR imaging spectrometers for CH 4 mapping: implications of band positioning, spectral sampling and noise [J]. International Journal of Applied Earth Observationand Geoinformation , 2021, 94: 102233.
[19] Funk C C, Theiler J, Roberts D A, et al . Clustering to improve matched filter detection of weak gas plumes in hyperspectral thermal imagery [J]. IEEE Transactions on Geoscience and Remote Sensing , 2001, 39(7): 1410-1420.