Identifying trend reversals in atmospheric ethane from a multi-site analysis

Marina Friedrich; Siem Jan Koopman; Yicong Lin; Emmanuel Mahieu; Stephan Smeekes; Martine De Mazière; Victoria Flood; Matthias Max Frey; Michel Grutter; James W. Hannigan; Frank Hase; Nicholas Jones; Rigel Kivi; Maria Makarova; Isamu Morino; Isao Murata; Tomoo Nagahama; Justus Notholt; Ivan Ortega; Maxime Prignon; Amelie Ninja Röhling; Dan Smale; Kimberly Strong; Yao Té; Minqiang Zhou

doi:10.1007/s10584-026-04153-0

Identifying trend reversals in atmospheric ethane from a multi-site analysis

Marina Friedrich
, Siem Jan Koopman
, Yicong Lin
, Emmanuel Mahieu
, Stephan Smeekes
, Martine De Mazière
, Victoria Flood
, Matthias Max Frey
, Michel Grutter
, James W. Hannigan
, Frank Hase
, Nicholas Jones
, Rigel Kivi
, Maria Makarova
, Isamu Morino
, Isao Murata
, Tomoo Nagahama
, Justus Notholt
, Ivan Ortega
, Maxime Prignon

Amelie Ninja Röhling, Dan Smale, Kimberly Strong, Yao Té, Minqiang Zhou

Vrije Universiteit Amsterdam
Tinbergen Institute - TI
University of Liege
Maastricht University
Royal Belgian Institute for Space Aeronomy
University of Toronto
Karlsruhe Institute of Technology
Universidad Nacional Autónoma de México
National Center for Atmospheric Research
University of Wollongong
Finnish Meteorological Institute
St. Petersburg State University
National Institute for Environmental Studies of Japan
Tohoku University
Nagoya University
University of Bremen
Chalmers University of Technology
NIWA
Sorbonne Université
CAS - Institute of Atmospheric Physics

Research output: Contribution to journal › Article › peer-review

Abstract

Ethane is the most abundant non-methane hydrocarbon in Earth’s atmosphere and acts as an indirect greenhouse gas, influencing the atmospheric lifetime of methane. Therefore, understanding the development of trends and identifying trend reversals in atmospheric ethane is crucial. Ethane abundance is measured at different ground-based stations worldwide using Fourier transform infrared remote sensing techniques. We compile a new dataset comprising 26 ethane time series from the Northern and Southern Hemispheres. We analyze their long-term trends using different econometric techniques capable of handling missing data and strong seasonal components present in the data. The resulting trend patterns are consistent across the different methods, with similar estimated trends at the various stations. In the Northern Hemisphere, the common trend across stations declined from the 1990s to 2005, gradually increased over the next decade, and then resumed a similar downward trajectory from 2015 onward. The estimated trends reveal a pronounced peak around 2014/2015, marking a reversal from an upward to a downward trend.

Original language	English
Article number	66
Journal	Climatic Change
Volume	179
Issue number	4
DOIs	https://doi.org/10.1007/s10584-026-04153-0
State	Published - Apr 2026
Externally published	Yes

Keywords

Atmospheric ethane
FTIR remote sensing
Kalman filter
Nonparametric trend analysis

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10.1007/s10584-026-04153-0

Cite this

Friedrich, M., Koopman, S. J., Lin, Y., Mahieu, E., Smeekes, S., De Mazière, M., Flood, V., Frey, M. M., Grutter, M., Hannigan, J. W., Hase, F., Jones, N., Kivi, R., Makarova, M., Morino, I., Murata, I., Nagahama, T., Notholt, J., Ortega, I., ... Zhou, M. (2026). Identifying trend reversals in atmospheric ethane from a multi-site analysis. Climatic Change, 179(4), Article 66. https://doi.org/10.1007/s10584-026-04153-0

@article{61d7483daf4b440281cbb33809da4526,

title = "Identifying trend reversals in atmospheric ethane from a multi-site analysis",

abstract = "Ethane is the most abundant non-methane hydrocarbon in Earth{\textquoteright}s atmosphere and acts as an indirect greenhouse gas, influencing the atmospheric lifetime of methane. Therefore, understanding the development of trends and identifying trend reversals in atmospheric ethane is crucial. Ethane abundance is measured at different ground-based stations worldwide using Fourier transform infrared remote sensing techniques. We compile a new dataset comprising 26 ethane time series from the Northern and Southern Hemispheres. We analyze their long-term trends using different econometric techniques capable of handling missing data and strong seasonal components present in the data. The resulting trend patterns are consistent across the different methods, with similar estimated trends at the various stations. In the Northern Hemisphere, the common trend across stations declined from the 1990s to 2005, gradually increased over the next decade, and then resumed a similar downward trajectory from 2015 onward. The estimated trends reveal a pronounced peak around 2014/2015, marking a reversal from an upward to a downward trend.",

keywords = "Atmospheric ethane, FTIR remote sensing, Kalman filter, Nonparametric trend analysis",

author = "Marina Friedrich and Koopman, \{Siem Jan\} and Yicong Lin and Emmanuel Mahieu and Stephan Smeekes and \{De Mazi{\`e}re\}, Martine and Victoria Flood and Frey, \{Matthias Max\} and Michel Grutter and Hannigan, \{James W.\} and Frank Hase and Nicholas Jones and Rigel Kivi and Maria Makarova and Isamu Morino and Isao Murata and Tomoo Nagahama and Justus Notholt and Ivan Ortega and Maxime Prignon and R{\"o}hling, \{Amelie Ninja\} and Dan Smale and Kimberly Strong and Yao T{\'e} and Minqiang Zhou",

note = "Publisher Copyright: {\textcopyright} The Author(s) 2026.",

year = "2026",

month = apr,

doi = "10.1007/s10584-026-04153-0",

language = "English",

volume = "179",

journal = "Climatic Change",

issn = "0165-0009",

publisher = "Springer Science and Business Media B.V.",

number = "4",

}

Friedrich, M, Koopman, SJ, Lin, Y, Mahieu, E, Smeekes, S, De Mazière, M, Flood, V, Frey, MM, Grutter, M, Hannigan, JW, Hase, F, Jones, N, Kivi, R, Makarova, M, Morino, I, Murata, I, Nagahama, T, Notholt, J, Ortega, I, Prignon, M, Röhling, AN, Smale, D, Strong, K, Té, Y & Zhou, M 2026, 'Identifying trend reversals in atmospheric ethane from a multi-site analysis', Climatic Change, vol. 179, no. 4, 66. https://doi.org/10.1007/s10584-026-04153-0

TY - JOUR

T1 - Identifying trend reversals in atmospheric ethane from a multi-site analysis

AU - Friedrich, Marina

AU - Koopman, Siem Jan

AU - Lin, Yicong

AU - Mahieu, Emmanuel

AU - Smeekes, Stephan

AU - De Mazière, Martine

AU - Flood, Victoria

AU - Frey, Matthias Max

AU - Grutter, Michel

AU - Hannigan, James W.

AU - Hase, Frank

AU - Jones, Nicholas

AU - Kivi, Rigel

AU - Makarova, Maria

AU - Morino, Isamu

AU - Murata, Isao

AU - Nagahama, Tomoo

AU - Notholt, Justus

AU - Ortega, Ivan

AU - Prignon, Maxime

AU - Röhling, Amelie Ninja

AU - Smale, Dan

AU - Strong, Kimberly

AU - Té, Yao

AU - Zhou, Minqiang

PY - 2026/4

Y1 - 2026/4

N2 - Ethane is the most abundant non-methane hydrocarbon in Earth’s atmosphere and acts as an indirect greenhouse gas, influencing the atmospheric lifetime of methane. Therefore, understanding the development of trends and identifying trend reversals in atmospheric ethane is crucial. Ethane abundance is measured at different ground-based stations worldwide using Fourier transform infrared remote sensing techniques. We compile a new dataset comprising 26 ethane time series from the Northern and Southern Hemispheres. We analyze their long-term trends using different econometric techniques capable of handling missing data and strong seasonal components present in the data. The resulting trend patterns are consistent across the different methods, with similar estimated trends at the various stations. In the Northern Hemisphere, the common trend across stations declined from the 1990s to 2005, gradually increased over the next decade, and then resumed a similar downward trajectory from 2015 onward. The estimated trends reveal a pronounced peak around 2014/2015, marking a reversal from an upward to a downward trend.

AB - Ethane is the most abundant non-methane hydrocarbon in Earth’s atmosphere and acts as an indirect greenhouse gas, influencing the atmospheric lifetime of methane. Therefore, understanding the development of trends and identifying trend reversals in atmospheric ethane is crucial. Ethane abundance is measured at different ground-based stations worldwide using Fourier transform infrared remote sensing techniques. We compile a new dataset comprising 26 ethane time series from the Northern and Southern Hemispheres. We analyze their long-term trends using different econometric techniques capable of handling missing data and strong seasonal components present in the data. The resulting trend patterns are consistent across the different methods, with similar estimated trends at the various stations. In the Northern Hemisphere, the common trend across stations declined from the 1990s to 2005, gradually increased over the next decade, and then resumed a similar downward trajectory from 2015 onward. The estimated trends reveal a pronounced peak around 2014/2015, marking a reversal from an upward to a downward trend.

KW - Atmospheric ethane

KW - FTIR remote sensing

KW - Kalman filter

KW - Nonparametric trend analysis

UR - https://www.scopus.com/pages/publications/105033607282

U2 - 10.1007/s10584-026-04153-0

DO - 10.1007/s10584-026-04153-0

M3 - Article

AN - SCOPUS:105033607282

SN - 0165-0009

VL - 179

JO - Climatic Change

JF - Climatic Change

IS - 4

M1 - 66

ER -

Identifying trend reversals in atmospheric ethane from a multi-site analysis

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Keywords

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