Spatio-temporal variation of outgoing thermal radiation of the earth by space-based IR spectrometer IKFS‑2

Yu. M. Timofeev; Тимофеев Ю. М.; G. M. Nerobelov; Неробелов Г. М.; D. A. Kozlov; Козлов Д. А.; I. S. Cherkashin; Черкашин И. С.; P. M. Nerobelov; Неробелов П. М.; A. N. Rublev; Рублев А. Н.; A. B. Uspensky; Успенский А. Б.; Yu. V. Kiseleva; Киселева Ю. В.

doi:10.31857/S0002351524030045

Spatio-temporal variation of outgoing thermal radiation of the earth by space-based IR spectrometer IKFS‑2

Authors: Timofeev Y.M.¹, Nerobelov G.M.¹^,2^,3, Kozlov D.A.⁴, Cherkashin I.S.⁴, Nerobelov P.M.¹^,5, Rublev A.N.⁶, Uspensky A.B.⁶, Kiseleva Y.V.⁶
Affiliations:
1. Saint Petersburg State University
2. Scientific Research Centre for Ecological Safety of the Russian Academy of Sciences
3. Russian State Hydrometeorological University
4. Keldysh Research Center
5. Peter the Great Saint Petersburg Polytechnic University
6. Planeta Scientific Research Centre (European Branch)
Issue: Vol 60, No 3 (2024)
Pages: 308-319
Section: Articles
URL: https://ogarev-online.ru/0002-3515/article/view/274361
DOI: https://doi.org/10.31857/S0002351524030045
EDN: https://elibrary.ru/JHZZFR
ID: 274361

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Abstract

Current Earth climate changes are caused by the violation of the planet’s radiation balance (RB). In this study the changes of the one of RB’s components – yearly and monthly averaged global and regional outgoing thermal radiation of Earth or the Earth own radiation (EOR) in a spectral range 660–1300 cm^-1 for 2015–2022 by IR Fourier-spectrometer IKFS-2 onboard the “Meteor-M” No2 satellite – is analyzed.

It is shown that EOR on a global scale in a range 660–1300 cm^-1 on average decreased during the period of 2015–2022. Mean integral radiation in the same wave-lenght range decreased by ~0.5 W m^-2 during 2015–2022. The most pronounced decrease of EOR was found in tropics, when the least pronounced – on polar latitudes. Besides, a negative trend of the integral EOR was found in tropics (up to 0.95–1.3 ± 0.1 W m^-2 for the 8 years) with relatively high coefficient of determination (0.46–0.57). At the same time, there is no pronounced trend of EOR on the polar and middle latitudes.

Keywords

radiation balance, Earth’s climate change, IKFS-2, Earth’s thermal radiation

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About the authors

Yu. M. Timofeev

Saint Petersburg State University

Email: akulishe95@mail.ru
Russian Federation, Saint Petersburg

G. M. Nerobelov

Saint Petersburg State University; Scientific Research Centre for Ecological Safety of the Russian Academy of Sciences; Russian State Hydrometeorological University

Author for correspondence.
Email: akulishe95@mail.ru
Russian Federation, Saint Petersburg; Saint Petersburg; Saint Petersburg

D. A. Kozlov

Keldysh Research Center

Email: akulishe95@mail.ru
Russian Federation, Moscow

I. S. Cherkashin

Keldysh Research Center

Email: akulishe95@mail.ru
Russian Federation, Moscow

P. M. Nerobelov

Saint Petersburg State University; Peter the Great Saint Petersburg Polytechnic University

Email: akulishe95@mail.ru
Russian Federation, Saint Petersburg; Saint Petersburg

A. N. Rublev

Planeta Scientific Research Centre (European Branch)

Email: akulishe95@mail.ru
Russian Federation, Moscow

A. B. Uspensky

Planeta Scientific Research Centre (European Branch)

Email: akulishe95@mail.ru
Russian Federation, Moscow

Yu. V. Kiseleva

Planeta Scientific Research Centre (European Branch)

Email: akulishe95@mail.ru
Russian Federation, Moscow

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2. Fig. 1. Difference spectra of the annual mean global PPE in the 660-1300 cm-1 range for 2016-2022 relative to 2015 based on ICFS-2 measurements

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3. Fig. 2. Temporal change of the annual average global integral PPE in the 660-1300 cm-1 spectral region for 2016-2022 relative to 2015 based on ICFS-2 measurements

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4. Fig. 3. Temporal change of the spectrum of the Earth's mean global NF in the spectral region 660-1300 cm-1 for 2016-2022 relative to 2015

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5. Fig. 4. Average 2015-2022 PPE spectra in the 660-1300 cm-1 range for six latitude zones based on ICFS-2 measurements

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6. Fig. 5. Difference spectra of annual mean PPE for 2016-2022 relative to 2015 in the 660-1300 cm-1 range in the northern (left) and southern (right) hemispheres for six latitude zones (90°N-90°S in 30° increments)

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7. Fig. 6. Average NMT difference spectra for 2016-2022 compared to 2015 in the 660-1300 cm-1 range in the northern (left) and southern (right) hemispheres of the Earth for six latitude zones (90°N-90°S in 30° increments)

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8. Fig. 7. Temporal changes of annual mean integrated PPE in the 660-1300 cm-1 spectral region for 2016-2022 relative to 2015 in the northern (a) and southern (b) hemispheres from ICFS-2 data

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9. Fig. 8. Time series of global mean monthly integrated PPE based on ICFS-2 data and MLR model for 2015-2022

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