A Unified Framework for Trend Uncertainty Assessment in Climate Data Records: Demonstration on Global Mean Sea Level

Kevin Gobron; Roland Hohensinn; Xavier Loizeau; Claire E. Bulgin; Christopher J. Merchant; Emma R. Woolliams; Maurice G. Cox; Wouter Dorigo; Thomas Howard; Mary Langsdale; Adam C. Povey; Michaël Ablain; Janusz Bogusz; Alexander Gruber; Anna Klos; Jonathan Mittaz

doi:10.1007/s10712-025-09922-7

A Unified Framework for Trend Uncertainty Assessment in Climate Data Records: Demonstration on Global Mean Sea Level

Kevin Gobron, Roland Hohensinn, Xavier Loizeau, Claire E. Bulgin, Christopher J. Merchant, Emma R. Woolliams, Maurice G. Cox, Wouter Dorigo, Thomas Howard, Mary Langsdale, Adam C. Povey, Michaël Ablain, Janusz Bogusz, Alexander Gruber, Anna Klos, Jonathan Mittaz

Department of Mathematical Sciences

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

Abstract

Trends of essential climate variables are often estimated from climate data records to quantify changes in the Earth system. An understanding of the uncertainty in a trend is essential for accurately determining the significance of a trend and attributing its causes. Despite this importance, trend-uncertainty estimates rarely account for all known sources of uncertainty. Common approaches neglect measurement-system instability or neglect the impact of natural variability on trend uncertainty. Such neglect can result in over-confidence in trend estimates. This study addresses trend-uncertainty assessment, particularly the need to account for the combined effects of measurement instability and natural variability on the trend uncertainty. The study presents a novel, unified framework for trend estimation that combines available measurement uncertainty information with empirical modelling of natural climate variability to achieve a more accurate uncertainty estimate. The framework is demonstrated for a time series of global mean sea level observations, obtaining more realistic trend-uncertainty values. The framework is applicable to most other climate data records. Adopting this approach will enhance confidence in climate change analysis through more accurate trend-uncertainty assessment in climate studies.

Original language	English
Journal	Surveys in Geophysics
Early online date	12 Jan 2026
DOIs	https://doi.org/10.1007/s10712-025-09922-7
Publication status	E-pub ahead of print - 12 Jan 2026

Data Availability Statement

The data used to produce this work is available at https://doi.org/10.17882/58344. The codes used to produce the results presented in this study will be accessible at the following Zenodo repository: https://doi.org/10.5281/zenodo.15387896. These codes are also available upon request.

Funding

This paper is an outcome of the Workshop ‘Remote Sensing in Climatology: Essential Climate Variables and their Uncertainties’ held at the International Space Science Institute (ISSI) in Bern, Switzerland (13-17 November 2023). Contributions to this paper were supported by the national capability funding for the National Centre for Earth Observation from the Natural Environment Research Council through award NE/R016518/1. For the purpose of open access, the authors have applied a Creative Commons Attribution (CC BY) licence to the Author Accepted Manuscript version arising from this submission. Kevin Gobron is grateful to the Centre National d’Étude Spatiales (CNES) for the postdoctoral fellowship that allowed him to contribute to this work. The input from the National Physical Laboratory was supported by the National Measurement System programme of the UK Government’s Department for Science, Innovation and Technology. Anna Klos and Janusz Bogusz are supported by the National Science Center (Poland), grant no. UMO-2022/45/B/ST10/00333. Author information

Funders	Funder number
Natural Environment Research Council	NE/R016518/1
National Science Centre	UMO-2022/45/B/ST10/00333.

Keywords

Climate data records
Essential climate variables
Measurement errors
Natural variability
Trend estimation
Uncertainty

ASJC Scopus subject areas

Geophysics
Geochemistry and Petrology

UN SDGs

This output contributes to the following UN Sustainable Development Goals (SDGs)

Access to Document

10.1007/s10712-025-09922-7Licence: CC BY-NC-ND

Cite this

Gobron, K., Hohensinn, R., Loizeau, X., Bulgin, C. E., Merchant, C. J., Woolliams, E. R., Cox, M. G., Dorigo, W., Howard, T., Langsdale, M., Povey, A. C., Ablain, M., Bogusz, J., Gruber, A., Klos, A., & Mittaz, J. (2026). A Unified Framework for Trend Uncertainty Assessment in Climate Data Records: Demonstration on Global Mean Sea Level. Surveys in Geophysics. Advance online publication. https://doi.org/10.1007/s10712-025-09922-7

Gobron, K, Hohensinn, R, Loizeau, X, Bulgin, CE, Merchant, CJ, Woolliams, ER, Cox, MG, Dorigo, W, Howard, T, Langsdale, M, Povey, AC, Ablain, M, Bogusz, J, Gruber, A, Klos, A & Mittaz, J 2026, 'A Unified Framework for Trend Uncertainty Assessment in Climate Data Records: Demonstration on Global Mean Sea Level', Surveys in Geophysics. https://doi.org/10.1007/s10712-025-09922-7

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abstract = "Trends of essential climate variables are often estimated from climate data records to quantify changes in the Earth system. An understanding of the uncertainty in a trend is essential for accurately determining the significance of a trend and attributing its causes. Despite this importance, trend-uncertainty estimates rarely account for all known sources of uncertainty. Common approaches neglect measurement-system instability or neglect the impact of natural variability on trend uncertainty. Such neglect can result in over-confidence in trend estimates. This study addresses trend-uncertainty assessment, particularly the need to account for the combined effects of measurement instability and natural variability on the trend uncertainty. The study presents a novel, unified framework for trend estimation that combines available measurement uncertainty information with empirical modelling of natural climate variability to achieve a more accurate uncertainty estimate. The framework is demonstrated for a time series of global mean sea level observations, obtaining more realistic trend-uncertainty values. The framework is applicable to most other climate data records. Adopting this approach will enhance confidence in climate change analysis through more accurate trend-uncertainty assessment in climate studies.",

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AU - Merchant, Christopher J.

AU - Woolliams, Emma R.

AU - Cox, Maurice G.

AU - Dorigo, Wouter

AU - Howard, Thomas

AU - Langsdale, Mary

AU - Povey, Adam C.

AU - Ablain, Michaël

AU - Bogusz, Janusz

AU - Gruber, Alexander

AU - Klos, Anna

AU - Mittaz, Jonathan

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N2 - Trends of essential climate variables are often estimated from climate data records to quantify changes in the Earth system. An understanding of the uncertainty in a trend is essential for accurately determining the significance of a trend and attributing its causes. Despite this importance, trend-uncertainty estimates rarely account for all known sources of uncertainty. Common approaches neglect measurement-system instability or neglect the impact of natural variability on trend uncertainty. Such neglect can result in over-confidence in trend estimates. This study addresses trend-uncertainty assessment, particularly the need to account for the combined effects of measurement instability and natural variability on the trend uncertainty. The study presents a novel, unified framework for trend estimation that combines available measurement uncertainty information with empirical modelling of natural climate variability to achieve a more accurate uncertainty estimate. The framework is demonstrated for a time series of global mean sea level observations, obtaining more realistic trend-uncertainty values. The framework is applicable to most other climate data records. Adopting this approach will enhance confidence in climate change analysis through more accurate trend-uncertainty assessment in climate studies.

AB - Trends of essential climate variables are often estimated from climate data records to quantify changes in the Earth system. An understanding of the uncertainty in a trend is essential for accurately determining the significance of a trend and attributing its causes. Despite this importance, trend-uncertainty estimates rarely account for all known sources of uncertainty. Common approaches neglect measurement-system instability or neglect the impact of natural variability on trend uncertainty. Such neglect can result in over-confidence in trend estimates. This study addresses trend-uncertainty assessment, particularly the need to account for the combined effects of measurement instability and natural variability on the trend uncertainty. The study presents a novel, unified framework for trend estimation that combines available measurement uncertainty information with empirical modelling of natural climate variability to achieve a more accurate uncertainty estimate. The framework is demonstrated for a time series of global mean sea level observations, obtaining more realistic trend-uncertainty values. The framework is applicable to most other climate data records. Adopting this approach will enhance confidence in climate change analysis through more accurate trend-uncertainty assessment in climate studies.

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KW - Measurement errors

KW - Natural variability

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KW - Uncertainty

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DO - 10.1007/s10712-025-09922-7

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A Unified Framework for Trend Uncertainty Assessment in Climate Data Records: Demonstration on Global Mean Sea Level

Abstract

Data Availability Statement

Funding

Keywords

ASJC Scopus subject areas

UN SDGs

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