Publications

Good, EJ; Aldred, FM; Ghent, DJ; Veal, KL; Jimenez, C (2022). An Analysis of the Stability and Trends in the LST_cci Land Surface Temperature Datasets Over Europe. EARTH AND SPACE SCIENCE, 9(9), e2022EA002317.

Abstract
Long-term satellite land surface temperature (LST) data are desirable to augment 2m air temperatures (T2m) measured in situ and as an independent measure of surface temperature change. However, previous studies show variable agreement between LST and T2m time series. The objective of this study is to assess the stability and trends in six new LST data sets from the European Space Agency's Climate Change Initiative for LST (LST_cci). LST anomalies are compared with homogenized station T2m anomalies over Europe, which verifies all six data sets are well coupled (LST vs T2m anomaly correlations and slopes: 0.6-0.9). The temporal stability of the LST_cci data is assessed through a comparison with the T2m anomaly time series. Only the LST_cci data sets for the MODerate resolution Imaging Spectroradiometer (MODIS) onboard Aqua and the Advanced Along-Track Scanning Radiometer (AATSR) appear stable; the MODIS/Terra, ATSR-2, and multisensor InfraRed and MicroWave data sets show non-climatic discontinuities associated with changes in sensor and/or drift over time. For MODIS/Aqua (2002-2018), significant trends in LST of 0.64-0.66 K/decade compare well with the equivalent T2m trends of 0.52-0.59 K/decade. The LST and T2m trends for AATSR (2002-2012) are found to be statistically insignificant, likely due to the comparatively short study period and specific years available for analysis. No evidence is found to suggest that trends calculated using cloud-free InfraRed observations are affected by clear-sky bias. This study suggests that satellite LST data can be used to assess warming trends over land and for other climate applications if the required homogeneity is assured. Plain Language Summary Long-term changes in surface temperature due to climate change are usually studied using near-surface air temperatures (T2m) from weather stations. However, these data are not available everywhere and changes in T2m are poorly understood in some regions (e.g., parts of Africa). This study assesses the potential for satellite-observed land surface temperatures (LST) to help fill these gaps. The study finds that LST and T2m provide very similar information on surface temperatures and therefore LST can provide useful information where T2m data are unavailable. However, some of the LST data sets are found to be unstable and suffer from jumps and changes over time that result from for example, changes in satellite instrument or a change in the orbit of the satellite platform. These unstable LST data sets cannot be used to measure changes in surface temperature. However, the study finds that for stable LST data sets, which do not suffer from these non-climatic jumps and changes, the changes in LST over time are very similar to, or even the same as, the changes in T2m. Therefore, this work suggests that satellite LST data could be used to measure changes in surface temperature where there are not enough stations to make these measurements using T2m.

DOI:
10.1029/2022EA002317

ISSN:
2333-5084