18.6.4.2 Gas Plume, Air Flow

Tseng, D.C.[Din-Chang], Shieh, W.S.[Wern-Sheng],
Plume extraction using entropic thresholding and region growing,
PR(26), No. 5, May 1993, pp. 805-817.
Elsevier DOI 0401
BibRef
Earlier:
Plume segmentation using local entropic thresholding,
ICPR92(III:156-159).
IEEE DOI 9208
Smoke plumes. BibRef

Peters, R.A., Nichols, J.A.,
Rocket Plume Image Sequence Enhancement Using 3D Operators,
AeroSys(33), No. 2, Part 1, April 1997, pp. 485-498. 9704
BibRef

Bushman, B.B.[Boyd B.],
Plume or combustion detection by time sequence differentiation,
US_Patent5,793,889, Aug 11, 1998
WWW Link. BibRef 9808

Funk, C.C., Theiler, J., Roberts, D.A., Borel, C.C.,
Clustering to improve matched filter detection of weak gas plumes in hyperspectral thermal imagery,
GeoRS(39), No. 7, July 2001, pp. 1410-1420.
IEEE Top Reference. 0108
BibRef

Marjovi, A., Marques, L.,
Optimal Swarm Formation for Odor Plume Finding,
Cyber(44), No. 12, December 2014, pp. 2302-2315.
IEEE DOI 1412
electronic noses BibRef

Nelson, D.L.[David L.], Garay, M.J.[Michael J.], Kahn, R.A.[Ralph A.], Dunst, B.A.[Ben A.],
Stereoscopic Height and Wind Retrievals for Aerosol Plumes with the MISR INteractive eXplorer (MINX),
RS(5), No. 9, 2013, pp. 4593-4628.
DOI Link 1310
BibRef

Gross, B.[Barry], Wu, Y.H.[Yong-Hua], Moshary, F.[Fred], Delgado, R.[Ruben], Hoff, R.[Ray], Su, J.[Jia], Lee, R.[Robert], McCormick, P.[Pat],
Using lidar networks to explore aloft plume properties,
SPIE(Newsroom), December 30, 2014
DOI Link 1504
A coordinated lidar network in the northeastern United States explored the optical properties of transported plumes from fires and dust and diagnosed chemical transport model concentration biases. BibRef

Fisher, D., Muller, J.P., Yershov, V.N.,
Automated Stereo Retrieval of Smoke Plume Injection Heights and Retrieval of Smoke Plume Masks From AATSR and Their Assessment With CALIPSO and MISR,
GeoRS(52), No. 2, February 2014, pp. 1249-1258.
IEEE DOI 1402
geophysical techniques BibRef

Pering, T.D.[Tom D.], McGonigle, A.J.S.[Andrew J. S.], Tamburello, G.[Giancarlo], Aiuppa, A.[Alessandro], Bitetto, M.[Marcello], Rubino, C.[Cosimo], Wilkes, T.C.[Thomas C.],
A Novel and Inexpensive Method for Measuring Volcanic Plume Water Fluxes at High Temporal Resolution,
RS(9), No. 2, 2017, pp. xx-yy.
DOI Link 1703
Comment on:
See also Difficulty of Measuring the Absorption of Scattered Sunlight by H2O and CO2 in Volcanic Plumes: A Comment on Pering et al. A Novel and Inexpensive Method for Measuring Volcanic Plume Water Fluxes at High Temporal Resolution, The. BibRef
And: Reply to comments: RS(9), No. 10, 2017, pp. xx-yy.
DOI Link 1711
BibRef

Kern, C.[Christoph],
The Difficulty of Measuring the Absorption of Scattered Sunlight by H2O and CO2 in Volcanic Plumes: A Comment on Pering et al. 'A Novel and Inexpensive Method for Measuring Volcanic Plume Water Fluxes at High Temporal Resolution',
RS(9), No. 6, 2017, pp. xx-yy.
DOI Link 1706

See also Novel and Inexpensive Method for Measuring Volcanic Plume Water Fluxes at High Temporal Resolution, A. BibRef

Tochon, G., Chanussot, J., Dalla Mura, M., Bertozzi, A.L.,
Object Tracking by Hierarchical Decomposition of Hyperspectral Video Sequences: Application to Chemical Gas Plume Tracking,
GeoRS(55), No. 8, August 2017, pp. 4567-4585.
IEEE DOI 1708
Chemicals, Hyperspectral imaging, Object detection, Object tracking, Shape, Video sequences, Binary partition tree, gas plume tracking, hyperspectral video sequence, object, detection BibRef

Osorio, M.[Matías], Casaballe, N.[Nicolás], Belsterli, G.[Gastón], Barreto, M.[Miguel], Gómez, Á.[Álvaro], Ferrari, J.A.[José A.], Frins, E.[Erna],
Plume Segmentation from UV Camera Images for SO2 Emission Rate Quantification on Cloud Days,
RS(9), No. 6, 2017, pp. xx-yy.
DOI Link 1706
BibRef

Marzano, F.S., Corradini, S., Mereu, L., Kylling, A., Montopoli, M., Cimini, D., Merucci, L., Stelitano, D.,
Multisatellite Multisensor Observations of a Sub-Plinian Volcanic Eruption: The 2015 Calbuco Explosive Event in Chile,
GeoRS(56), No. 5, May 2018, pp. 2597-2612.
IEEE DOI 1805
Clouds, Laser radar, MODIS, Microwave radiometry, Satellite broadcasting, Spatial resolution, Volcanoes, volcanic plume BibRef

Marchese, F.[Francesco], Falconieri, A.[Alfredo], Pergola, N.[Nicola], Tramutoli, V.[Valerio],
Monitoring the Agung (Indonesia) Ash Plume of November 2017 by Means of Infrared Himawari 8 Data,
RS(10), No. 6, 2018, pp. xx-yy.
DOI Link 1806
BibRef

de Donato, P.[Philippe], Barres, O.[Odile], Sausse, J.[Judith], Martin, D.[Delphine],
Near Real-Time Ground-to-Ground Infrared Remote-Sensing Combination and Inexpensive Visible Camera Observations Applied to Tomographic Stack Emission Measurements,
RS(10), No. 5, 2018, pp. xx-yy.
DOI Link 1806
Evaluation of the environmental impact of gas plumes from stack emissions. BibRef

Scafutto, R.D.P.M.[Rebecca Del Papa Moreira], de Souza Filho, C.R.[Carlos Roberto],
Detection of Methane Plumes Using Airborne Midwave Infrared (3-5 µm) Hyperspectral Data,
RS(10), No. 8, 2018, pp. xx-yy.
DOI Link 1809
BibRef

Bredemeyer, S.[Stefan], Ulmer, F.G.[Franz-Georg], Hansteen, T.H.[Thor H.], Walter, T.R.[Thomas R.],
Radar Path Delay Effects in Volcanic Gas Plumes: The Case of Láscar Volcano, Northern Chile,
RS(10), No. 10, 2018, pp. xx-yy.
DOI Link 1811
BibRef

Wood, K.[Kieran], Thomas, H.[Helen], Watson, M.[Matt], Calway, A.[Andrew], Richardson, T.[Tom], Stebel, K.[Kerstin], Naismith, A.[Ailsa], Berthoud, L.[Lucy], Lucas, J.[Josh],
Measurement of three dimensional volcanic plume properties using multiple ground based infrared cameras,
PandRS(154), 2019, pp. 163-175.
Elsevier DOI 1907
3D reconstruction, Volcano, Plume, Thermal, Space carving BibRef

Williams, D.B.[Daniel B.], Ramsey, M.S.[Michael S.],
On the Applicability of Laboratory Thermal Infrared Emissivity Spectra for Deconvolving Satellite Data of Opaque Volcanic Ash Plumes,
RS(11), No. 19, 2019, pp. xx-yy.
DOI Link 1910
BibRef

Scollo, S.[Simona], Boselli, A.[Antonella], Corradini, S.[Stefano], Leto, G.[Giuseppe], Guerrieri, L.[Lorenzo], Merucci, L.[Luca], Prestifilippo, M.[Michele], Sanchez, R.Z.[Ricardo Zanmar], Sannino, A.[Alessia], Stelitano, D.[Dario],
Multi-Sensor Analysis of a Weak and Long-Lasting Volcanic Plume Emission,
RS(12), No. 23, 2020, pp. xx-yy.
DOI Link 2012
BibRef

Mims, S.R., Kahn, R.A., Moroney, C.M., Gaitley, B.J., Nelson, D.L., Garay, M.J.,
MISR Stereo Heights of Grassland Fire Smoke Plumes in Australia,
GeoRS(48), No. 1, January 2010, pp. 25-35.
IEEE DOI 1001
BibRef

Pailot-Bonnétat, S.[Sophie], Harris, A.J.L.[Andrew J. L.], Calvari, S.[Sonia], de Michele, M.[Marcello], Gurioli, L.[Lucia],
Plume Height Time-Series Retrieval Using Shadow in Single Spatial Resolution Satellite Images,
RS(12), No. 23, 2020, pp. xx-yy.
DOI Link 2012
BibRef

Sellitto, P.[Pasquale], Salerno, G.[Giuseppe], Doussin, J.F.[Jean-François], Triquet, S.[Sylvain], Dulac, F.[François], Desboeufs, K.[Karine],
Photometric Observations of Aerosol Optical Properties and Emission Flux Rates of Stromboli Volcano Plume during the PEACETIME Campaign,
RS(13), No. 19, 2021, pp. xx-yy.
DOI Link 2110
BibRef

Lu, X.M.[Xiao-Man], Zhang, X.Y.[Xiao-Yang], Li, F.J.[Fang-Jun], Cochrane, M.A.[Mark A.], Ciren, P.[Pubu],
Detection of Fire Smoke Plumes Based on Aerosol Scattering Using VIIRS Data over Global Fire-Prone Regions,
RS(13), No. 2, 2021, pp. xx-yy.
DOI Link 2101
BibRef

Konovalov, I.B.[Igor B.], Golovushkin, N.A.[Nikolai A.], Beekmann, M.[Matthias], Turquety, S.[Solène],
Using Multi-Platform Satellite Observations to Study the Atmospheric Evolution of Brown Carbon in Siberian Biomass Burning Plumes,
RS(14), No. 11, 2022, pp. xx-yy.
DOI Link 2206
BibRef

Martins, L.[Leonardo], Guede-Fernández, F.[Federico], de Almeida, R.V.[Rui Valente], Gamboa, H.[Hugo], Vieira, P.[Pedro],
Real-Time Integration of Segmentation Techniques for Reduction of False Positive Rates in Fire Plume Detection Systems during Forest Fires,
RS(14), No. 11, 2022, pp. xx-yy.
DOI Link 2206
BibRef

Attiya, A.A.[Ali A.], Jones, B.G.[Brian G.],
Impact of Smoke Plumes Transport on Air Quality in Sydney during Extensive Bushfires (2019) in New South Wales, Australia Using Remote Sensing and Ground Data,
RS(14), No. 21, 2022, pp. xx-yy.
DOI Link 2212
BibRef

Simionato, R.[Riccardo], Jarvis, P.A.[Paul A.], Rossi, E.[Eduardo], Bonadonna, C.[Costanza],
PlumeTraP: A New MATLAB-Based Algorithm to Detect and Parametrize Volcanic Plumes from Visible-Wavelength Images,
RS(14), No. 7, 2022, pp. xx-yy.
DOI Link 2205
BibRef

Calassou, G.[Gabriel], Foucher, P.Y.[Pierre-Yves], Léon, J.F.[Jean-François],
Industrial Plume Properties Retrieved by Optimal Estimation Using Combined Hyperspectral and Sentinel-2 Data,
RS(13), No. 10, 2021, pp. xx-yy.
DOI Link 2105
BibRef

Phillips, M.C.[Mark C.], Bernacki, B.E.[Bruce E.], Conry, P.T.[Patrick T.], Brown, M.J.[Michael J.],
Standoff Infrared Measurements of Chemical Plume Dynamics in Complex Terrain Using a Combination of Active Swept-ECQCL Laser Spectroscopy with Passive Hyperspectral Imaging,
RS(14), No. 15, 2022, pp. xx-yy.
DOI Link 2208
BibRef

Tello, J.F.G.[José Francisco Guerrero], Coltelli, M.[Mauro], Marsella, M.[Maria], Celauro, A.[Angela], Baena, J.A.P.[José Antonio Palenzuela],
Convolutional Neural Network Algorithms for Semantic Segmentation of Volcanic Ash Plumes Using Visible Camera Imagery,
RS(14), No. 18, 2022, pp. xx-yy.
DOI Link 2209
BibRef

Bedoya-Velásquez, A.E.[Andres E.], Hoyos-Restrepo, M.[Manuela], Barreto, A.[Africa], García, R.D.[Rosa D.], Romero-Campos, P.M.[Pedro Miguel], García, O.[Omaira], Ramos, R.[Ramón], Roininen, R.[Reijo], Toledano, C.[Carlos], Sicard, M.[Michaël], Ceolato, R.[Romain],
Estimation of the Mass Concentration of Volcanic Ash Using Ceilometers: Study of Fresh and Transported Plumes from La Palma Volcano,
RS(14), No. 22, 2022, pp. xx-yy.
DOI Link 2212
BibRef

Kurchaba, S.[Solomiia], van Vliet, J.[Jasper], Verbeek, F.J.[Fons J.], Meulman, J.J.[Jacqueline J.], Veenman, C.J.[Cor J.],
Supervised Segmentation of NO2 Plumes from Individual Ships Using TROPOMI Satellite Data,
RS(14), No. 22, 2022, pp. xx-yy.
DOI Link 2212
BibRef

Ren, X.[Xin], Ding, D.[Dong], Qin, H.[Haosen], Ma, L.[Le], Li, G.X.[Guang-Xue],
Extraction of Submarine Gas Plume Based on Multibeam Water Column Point Cloud Model,
RS(14), No. 17, 2022, pp. xx-yy.
DOI Link 2209
BibRef

Labati, R.D.[R. Donida], Genovese, A., Piuri, V., Scotti, F.,
Wildfire Smoke Detection Using Computational Intelligence Techniques Enhanced With Synthetic Smoke Plume Generation,
SMCS(43), No. 4, 2013, pp. 1003-1012.
IEEE DOI 1307
lattice Boltzmann; neural networks; wildfire BibRef

García, R.D.[Rosa Delia], García, O.E.[Omaira Elena], Cuevas-Agulló, E.[Emilio], Barreto, Á.[África], Cachorro, V.E.[Victoria Eugenia], Marrero, C.[Carlos], Almansa, F.[Fernando], Ramos, R.[Ramón], Pó, M.[Mario],
Spectral Aerosol Radiative Forcing and Efficiency of the La Palma Volcanic Plume over the Izana Observatory,
RS(15), No. 1, 2023, pp. xx-yy.
DOI Link 2301
BibRef

Koushafar, M.[Mohammad], Sohn, G.[Gunho], Gordon, M.[Mark],
Deep Convolutional Neural Network for Plume Rise Measurements in Industrial Environments,
RS(15), No. 12, 2023, pp. xx-yy.
DOI Link 2307
BibRef

Li, R.G.[Rui-Guo], Wu, H.N.[Huai-Ning],
Multi-Robot Plume Source Localization by Distributed Quantum-Inspired Guidance With Formation Behavior,
ITS(24), No. 11, November 2023, pp. 11889-11904.
IEEE DOI 2311
BibRef

Stroud, J.R.[Jasper R.], Dienstfrey, W.J.[William J.], Plusquellic, D.F.[David F.],
Study on Local Power Plant Emissions Using Multi-Frequency Differential Absorption LIDAR and Real-Time Plume Tracking,
RS(15), No. 17, 2023, pp. 4283.
DOI Link 2310
BibRef

Li, C.[Chao], Wang, X.H.[Xian-Hua], Ye, H.[Hanhan], Wu, S.C.[Shi-Chao], Shi, H.L.[Hai-Liang], Luo, H.Y.[Hai-Yan], Li, Z.W.[Zhi-Wei], Xiong, W.[Wei], Li, D.C.[Da-Cheng], Sun, E.[Erchang], An, Y.[Yuan],
Evaluation of Simulated CO2 Point Source Plumes from High-Resolution Atmospheric Transport Model,
RS(15), No. 18, 2023, pp. 4518.
DOI Link 2310
BibRef

Chen, W.G.[Wen-Guang], Wang, X.[Xiao], Yan, B.L.[Bing-Long], Chen, J.J.[Jun-Jie], Jiang, T.C.[Ting-Chen], Sun, J.L.[Jia-Long],
Gas Plume Target Detection in Multibeam Water Column Image Using Deep Residual Aggregation Structure and Attention Mechanism,
RS(15), No. 11, 2023, pp. 2896.
DOI Link 2306
BibRef

Li, Q.[Qidi], Qian, Y.Y.[Yuan-Yuan], Luo, Y.H.[Yu-Han], Cao, L.[Le], Zhou, H.J.[Hai-Jin], Yang, T.P.[Tai-Ping], Si, F.Q.[Fu-Qi], Liu, W.Q.[Wen-Qing],
Diffusion Height and Order of Sulfur Dioxide and Bromine Monoxide Plumes from the Hunga Tonga-Hunga Ha'apai Volcanic Eruption,
RS(15), No. 6, 2023, pp. 1534.
DOI Link 2304
BibRef

Vita, F.[Fabio], Schiavo, B.[Benedetto], Inguaggiato, C.[Claudio], Inguaggiato, S.[Salvatore], Mazot, A.[Agnes],
Environmental and Volcanic Implications of Volatile Output in the Atmosphere of Vulcano Island Detected Using SO2 Plume (2021-23),
RS(15), No. 12, 2023, pp. xx-yy.
DOI Link 2307
BibRef

Mukai, S.[Sonoyo], Hioki, S.[Souichiro], Nakata, M.[Makiko],
Biomass Burning Plume from Simultaneous Observations of Polarization and Radiance at Different Viewing Directions with SGLI,
RS(15), No. 22, 2023, pp. 5405.
DOI Link 2311
BibRef

Mota, R.[Rui], Pacheco, J.M.[José M.], Pimentel, A.[Adriano], Gil, A.[Artur],
Monitoring Volcanic Plumes and Clouds Using Remote Sensing: A Systematic Review,
RS(16), No. 10, 2024, pp. 1789.
DOI Link 2405
BibRef

Couture, H.D.[Heather D.], Alvara, M.[Madison], Freeman, J.[Jeremy], Davitt, A.[Aaron], Koenig, H.[Hannes], Kargar, A.R.[Ali Rouzbeh], O'Connor, J.[Joseph], Soldner-Rembold, I.[Isabella], Ferreira, A.[Andr©], Jeyaratnam, J.[Jeyavinoth], Lewis, J.[Jordan], McCormick, C.[Colin], Nakano, T.[Tiffany], Dalisay, C.[Charmaine], Lewis, C.[Christy], Volpato, G.[Gabriela], Gray, M.[Matthew], McCormick, G.[Gavin],
Estimating Carbon Dioxide Emissions from Power Plant Water Vapor Plumes Using Satellite Imagery and Machine Learning,
RS(16), No. 7, 2024, pp. 1290.
DOI Link 2404
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Liang, J.[Jiakun], Griswold, J.D.S.[Jennifer D. Small],
Characteristics of Yellow Sea Fog under the Influence of Eastern China Aerosol Plumes,
RS(16), No. 13, 2024, pp. 2262.
DOI Link 2407
BibRef

Wang, H.Z.[Hong-Zhou], Fan, X.T.[Xiang-Tao], Jian, H.[Hongdeng], Yan, F.[Fuli],
Exploiting the Matched Filter to Improve the Detection of Methane Plumes with Sentinel-2 Data,
RS(16), No. 6, 2024, pp. 1023.
DOI Link 2403
BibRef

Li, Y.H.[Yi-Han], Hu, H.Y.[Hai-Yang], Wang, Q.[Qiang],
Non-Dominated Sorting Genetic Algorithm II (NSGA2)-Based Parameter Optimization of the MSMGWB Model Used in Remote Infrared Sensing Prediction for Hot Combustion Gas Plume,
RS(16), No. 17, 2024, pp. 3116.
DOI Link 2409
BibRef

Sun, E.[Erchang], Wu, S.C.[Shi-Chao], Wang, X.H.[Xian-Hua], Ye, H.[Hanhan], Shi, H.L.[Hai-Liang], An, Y.[Yuan], Li, C.[Chao],
Deep Learning Methods for Inferring Industrial CO2 Hotspots from Co-Emitted NO2 Plumes,
RS(17), No. 7, 2025, pp. 1167.
DOI Link 2504
BibRef

La Haye, N.[Nicholas], Easley, A.[Anastasija], Yun, K.[Kyongsik], Lee, H.[Hugo], Linstead, E.[Erik], Garay, M.J.[Michael J.], Kalashnikova, O.V.[Olga V.],
Development and Application of Self-Supervised Machine Learning for Smoke Plume and Active Fire Identification from the Fire Influence on Regional to Global Environments and Air Quality Datasets,
RS(17), No. 7, 2025, pp. 1267.
DOI Link 2504
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Zhang, L.[Lei], Xu, L.[Liang],
A 3D Reconstruction of Gas Cloud Leakage Based on Multi-Spectral Imaging Systems,
RS(17), No. 10, 2025, pp. 1786.
DOI Link 2505
BibRef

Nesme, N., Foucher, P.Y., Doz, S.,
Detection and Quantification of Industrial Methane Plume with The Airborne Hyspex-neo Camera and Applications to Satellite Data,
ISPRS20(B3:821-827).
DOI Link 2012
BibRef

Calassou, G., Foucher, P.Y., Leon, J.F.,
Aerosol Plumes Characterization By Hyperspectral Images Coupled With Sentinel-2 Products,
ISPRS20(B3:791-797).
DOI Link 2012
BibRef

Eu, K.S.[Kok Seng], Yap, K.M.[Kian Meng], Tan, W.C.[Wan Chew],
A Simulation Study of Micro-Drone Chemical Plume Tracking Performance in Tree Farm Environments,
IVIC17(260-269).
Springer DOI 1711
BibRef

Xu, Y., Wu, Z., Wei, Z., Dalla Mura, M., Chanussot, J., Bertozzi, A.,
GAS plume detection in hyperspectral video sequence using low rank representation,
ICIP16(2221-2225)
IEEE DOI 1610
Decision support systems BibRef

Bombrun, M.[Maxime], Barra, V.[Vincent], Harris, A.[Andrew],
Analysis of Thermal Video for Coarse to Fine Particle Tracking in Volcanic Explosion Plumes,
SCIA15(366-376).
Springer DOI 1506
BibRef

Hu, H.[Huiyi], Sunu, J.[Justin], Bertozzi, A.L.[Andrea L.],
Multi-class Graph Mumford-Shah Model for Plume Detection Using the MBO scheme,
EMMCVPR15(209-222).
Springer DOI 1504

See also Hyperspectral Image Classification Using Graph Clustering Methods. BibRef

Villarreal, B.L.[B. Lorena], Olague, G.[Gustavo], Gordillo, J.L.,
Odor Plume Tracking Algorithm Inspired on Evolution,
MCPR14(321-330).
Springer DOI 1407
BibRef

Merkurjev, E.[Ekaterina], Sunu, J.[Justin], Bertozzi, A.L.[Andrea L.],
Graph MBO method for multiclass segmentation of hyperspectral stand-off detection video,
ICIP14(689-693)
IEEE DOI 1502
Chemical plumes. BibRef

Wan, V.[Victoria], Braun, W.J., Dean, C.B.[Charmaine B.], Henderson, S.,
A comparison of classification algorithms for the identification of smoke plumes from satellite images,
CGC10(332).
PDF File. 1006
BibRef

Chapter on Optical Flow Field Computations and Use continues in
Wind Turbine Wakes, Wind Turbines .