eprintid: 36916
rev_number: 14
eprint_status: archive
userid: 9162
dir: disk0/00/03/69/16
datestamp: 2025-07-24 08:01:16
lastmod: 2025-07-24 08:01:48
status_changed: 2025-07-24 08:01:16
type: doctoralThesis
metadata_visibility: show
creators_name: Hofmann, Dennis
title: Investigating Air-Water Gas Transfer via Fluorescence Imaging
subjects: ddc-530
divisions: i-130500
adv_faculty: af-13
abstract: This study presents an advanced Fluorescence Imaging technique to make air-water gas exchange dynamics in a wind-wave facility visible up to high wind speeds. Fluorescence is generated by the pH-sensitive dye pyranine, which transitions into its fluorescent alkaline form upon reacting with the invading alkaline trace gas methylamine. A high-intensity laser illumination system combined with a multi-camera setup is implemented at the Heidelberg Aeolotron, enabling high-resolution imaging of fluorescent patterns in gas concentration fields near the water surface. Near-surface turbulent structures such as quasi-streamwise vortices, Langmuir circulations, and microscale wave breaking are identified. A major achievement is the development of a simulation-based method for estimating water-side gas transfer velocities. By modeling one-dimensional mass transport using the Small Eddy Model and comparing simulated fluorescence time series to experimental data, a robust determination of turbulence profiles and gas transfer velocities with uncertainties between 5% and 20% is established. Additionally, an algorithm is developed to detect and track microscalewave breaking events, combining structure tensor-based Oriented FAST and Rotated BRIEF detection, cluster analysis, and optical flow techniques. Based on the detected microscale wave breaking statistics, a first quantitative estimate suggests that microscale wave breaking contributes approximately 35% to 80% of the total water-side gas transfer velocity within a friction velocity range of 0.3 cm/s to 0.8 cm/s.
date: 2025
id_scheme: DOI
id_number: 10.11588/heidok.00036916
own_urn: urn:nbn:de:bsz:16-heidok-369166
date_accepted: 2025-07-10
advisor: HASH(0x556029e9a098)
language: eng
bibsort: HOFMANNDENINVESTIGAT2025
full_text_status: public
place_of_pub: Heidelberg
citation:   Hofmann, Dennis  (2025) Investigating Air-Water Gas Transfer via Fluorescence Imaging.  [Dissertation]     
document_url: https://archiv.ub.uni-heidelberg.de/volltextserver/36916/1/Dissertation_Dennis_Hofmann.pdf