the Creative Commons Attribution 4.0 License.
the Creative Commons Attribution 4.0 License.
| 15 May 2025
Observed changes in the temperature and height of the globally resolved lapserate tropopause
Abstract. The tropopause is a key indicator of atmospheric climate change, influenced by both the troposphere and stratosphere. Here we present a global view of tropopause changes, using high-resolution GNSS radio occultation data from 2002 to 2024. We identify significant trends in lapse rate tropopause (LRT) temperature and height with seasonal and regional detail. The tropical LRT has warmed, with particularly strong warming (> 1 K/decade) over the South Pacific during austral spring and summer, while height changes remain largely insignificant. Outside the tropics, LRT temperature changes are confined to southern high latitudes in winter, showing cooling of up to 1 K/decade. Notably, LRT height has increased significantly across most extratropical regions, with localized trends exceeding 200 m/decade over Asia and the Middle East during Northern Hemisphere winter. An exception is the LRT height decreases over the South Pacific, coinciding with a LRT warming in that region. These results highlight the interrelated effects of tropospheric and stratospheric changes and demonstrate the value of precise tropopause monitoring for detecting ongoing changes in the global climate system.
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Status: final response (author comments only)
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RC1: 'Comment on egusphere-2025-2100', Anonymous Referee #1, 23 Jun 2025
The comment was uploaded in the form of a supplement: https://egusphere.copernicus.org/preprints/2025/egusphere-2025-2100/egusphere-2025-2100-RC1-supplement.pdf
- AC1: 'Reply on RC1', Florian Ladstädter, 15 Sep 2025
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RC2: 'Comment on egusphere-2025-2100', Anonymous Referee #2, 14 Jul 2025
The study by Ladstaedter et al. shows Global Navigation satellite based temperature analysis of the tropopause altitude and temperature. The analysis covers 2002-2024 and provides a global view on the tropopause using the lapse rate tropopause LRT according to WMO. The authors further apply multiple linear regression with regressors for QBO and ENSO to derive trends of the LRT-height, and the LRT temperature. Seasonally and regionally resolved trends are presented. The authors also check for trend robustness with regard to the end date of data set.
They find a significant positive temperature increase at the LRT in the tropics and southern subtropics over time with, but no significant rise in LRT altitude. Instead the northern extratropics show an increase in LRT-height, and partly weak positive trend.Despite providing no analysis for the trend differences the paper provides extremely interesting data to the community. It is very well written, Figures are clear and the topic is well within the scope of ACP.
I recommend the paper for publication with just very few minor remarks to be considered and which are given below.Data:
1) Given the change of available profiles from COSMIC in the year 2007: How does this affect the trend estimates and statistics?2) Though the GNSSS data are a valuable and well established data set for deriving tropopause altitudes, the authors should provide in this manuscript a short paragraph on temperature uncertainties since they derive temperature trends here, despite given in other literature sources.
Methods: Regarding potential multiple tropopauses: How are these treated?
Does the analysis take the upper, or the lower one, or exclude such multiple cases particularly in the subtropics?Citation: https://doi.org/10.5194/egusphere-2025-2100-RC2 - AC2: 'Reply on RC2', Florian Ladstädter, 15 Sep 2025
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