17O-excess in tropical cyclones reflects local rain re-evaporation more than moisture source conditions

17O-excess is a relatively new water isotope parameter that could potentially provide useful information about the hydrological cycle. Previous works focusing on 17O-excess in polar regions suggest that it primarily tracks moisture source relative humidity, but little is known about how to interpret...

Full description

Saved in:
Bibliographic Details
Main Authors: Sun, Chijun, Shanahan, Timothy, He, Shaoneng, Bailey, Adriana, Nusbaumer, Jesse, Hu, Jun, Hillman, Aubrey, Ornouski, Erika, Warner, Jacob, DeLong, Kristine
Other Authors: Earth Observatory of Singapore
Format: Article
Language:English
Published: 2024
Subjects:
Online Access:https://hdl.handle.net/10356/175615
Tags: Add Tag
No Tags, Be the first to tag this record!
Institution: Nanyang Technological University
Language: English
Description
Summary:17O-excess is a relatively new water isotope parameter that could potentially provide useful information about the hydrological cycle. Previous works focusing on 17O-excess in polar regions suggest that it primarily tracks moisture source relative humidity, but little is known about how to interpret 17O-excess data in lower latitudes. Here we present quasi-hourly triple oxygen isotope data of precipitation collected from two tropical cyclones in Texas and Louisiana in 2020 to understand the impacts of environmental and meteorological processes on the 17O-excess of low-to mid-latitude precipitation. We find that at both hourly timescales and the event scale, 17O-excess is strongly correlated to changes in on-site rainfall intensity and relative humidity, which is consistent with the theory that the isotopic fractionation associated with rain re-evaporation lowers the 17O-excess of the remaining droplet. In addition, although evaporative conditions at the moisture source region may also influence 17O-excess of water vapor transported to the precipitation site, their impacts are likely overprinted by the post-condensation rain re-evaporation processes. Our results thus suggest that 17O-excess can be used as a proxy for local rather than source region evaporative conditions during tropical cyclones.