Tritium as a hydrological tracer in Mediterranean precipitation events

Tobias R Juhlke,Sébastien Santoni,Jürgen Sültenfuß,Robert Van Geldern,Emilie Garel,Frédéric Huneau,Katja Trachte,Johannes A C Barth

doi:10.5194/acp-20-3555-2020

Abstract

Abstract. Climate models are in need of improved constraints for water vapor transport in the atmosphere, and tritium can serve as a powerful tracer in the hydrological cycle. Although the general principles of tritium distribution and transfer processes within and between the various hydrological compartments are known, variation on short timescales and aspects of altitude dependence are still under debate. To address questions regarding tritium sources, sinks, and transfer processes, the sampling of individual precipitation events in Corte on the island of Corsica in the Mediterranean Sea was performed between April 2017 and April 2018. Tritium concentrations of 46 event samples were compared to their moisture origin and corresponding air mass history. Air mass back-trajectories were generated from the novel high-resolution ERA5 dataset from the ECMWF (European Centre for Medium-Range Weather Forecasts). Geographical source regions with similar tritium concentrations were predefined using generally known tritium distribution patterns, such as the “continental effect”, and from data records derived at long-term measurement stations of tritium in precipitation across the working area. Our model-derived source region tritium concentrations agreed well with annual mean station values. Moisture that originated from continental Europe and the Atlantic Ocean was most distinct regarding tritium concentrations with values up to 8.8 TU (tritium units) and near 0 TU, respectively. The seasonality of tritium values ranged from 1.6 TU in January to 10.1 TU in May, and they exhibited well-known elevated concentrations in spring and early summer due to increased stratosphere–troposphere exchange. However, this pattern was interrupted by extreme events. The average altitude of trajectories was correlated with the tritium concentrations in precipitation, especially in spring and early summer and if outlier values of extreme tritium concentrations were excluded. However, in combination with the trajectory information, these outlier values proved to be valuable for improving the comprehension of tritium movement in the atmosphere. Our work shows how event-based tritium research can advance the understanding of its distribution in the atmosphere.

Highlights

The hydrologic cycle is one of the key components in today’s climate models that predict the evolution of climate parameters in the face of climate change
The relative contribution of moisture to the 46 precipitation samples that originated from the five tritium source re
In conjunction with the measurement of the tritium concentrations of these precipitation events and the assumption of regionally similar tritium source values, this allowed for the identification of regions with a notable influence on the tritium content

Summary

Introduction

The hydrologic cycle is one of the key components in today’s climate models that predict the evolution of climate parameters in the face of climate change. An improved constraint of model input parameters, such as atmospheric moisture transport, has gained increased scientific interest (Flato et al, 2013). Cloud formation (Seinfeld et al, 2016) and planetary boundary layer (PBL) representation. Juhlke et al.: Tritium as a hydrological tracer in Mediterranean precipitation events (Teixeira et al, 2008) are considered to be some of the main sources of error in model scenarios. In addition to computational advances, measurements of hydrochemical parameters can serve to better constrain moisture transport patterns. Ideal parameters for this task should directly trace the movement of the water molecule itself

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Conclusion