Heat flow over a gas hydrate deposit in the Danube paleodelta: cruise MN249, 10-20/09/2023-Reference-Cited by-同舟云学术

Heat flow over a gas hydrate deposit in the Danube paleodelta: cruise MN249, 10-20/09/2023

Published:2023-12 Issue:3 Volume:84 Page:223-226
ISSN:0007-3938
Container-title:Review of the Bulgarian Geological Society
language:en
Short-container-title:Rev. Bulg. Geol. Soc.

Author:

Vasilev Atanas,Petsinski Petar,Hristova Raina,Pehlivanova Rosica

Abstract

This work presents results from the first purposeful in situ temperature measurements in seafloor sediments above a scalable gas hydrate deposit in the deep-water Danube paleodelta. Temperatures and temperature gradients with accuracy 5 mK and sensitivity 1 mK are measured with 3 MTL loggers with clamps (Antares GmbH) welded to a gravity corer with length of 6 m, outer diameter of 130 mm and weight ~300 kg. During the cruise MN249 on board of the Romanian R/V Mare Nigrum 10-20/10/2023, the gravity corer was deployed on 23 stations with successful temperature measurements and >3 m sediments lifting on 11 stations. Temperature gradients above the gas hydrate deposit (BSR area) are in ~20–50 mK/m when the background is ~30 mK/m. Additional data needed to determine the effects from the 2 main factors formatting temperature gradients – gas hydrate masses and sedimentation rates.

Publisher

Bulgarian Geological Society

Subject

General Medicine

Reference7 articles.

1. Bialas, J., T. Bohlen, A. Dannowski, G. Eisenberg-Klein, L. Gassner, R. Gehrmann, K. Heeschen, S. Hölz, M. Jegen, I. Klaucke, M. Krieger, J. Mann, C. Müller, J. Prüßmann, J. Schicks, E. Schünemann, K. Schwalenberg, M. Sommer, P. L. Smilde, E. Spangenberg, H. Trappe, T. Zander. 2020. Joint interpretation of geophysical field experiments in the Danube deep-sea fan, Black Sea. – Mar. Pet. Geol., 121, 104551; https://doi.org/10.1016/j.marpetgeo.2020.104551.

2. Popescu, I., M. de Batist, G. Lericolais, H. Nouzé, J. Poort, N. Panin, W. Versteeg, H. Gillet. 2006. Multiple bottom-simulating reflections in the Black Sea: Potential proxies of past climate conditions. – Mar. Geol., 227, 163–176; https://doi.org/10.1016/j.margeo.2005.12.006.

3. Riedel, M., J. Bialas, M. Haeckel, 2020. Heat flow data during Maria S. Merian cruise MSM34/2. PANGAEA; https://doi.org/10.1594/PANGAEA.912221.

4. Riedel, M., J. Bialas, H. Villinger, T. Pape, M. Haeckel, G. Bohrmann. 2021a. Heat flow measurements at the Danube Deep-Sea Fan, Western Black Sea. – Geosciences, 11, 240; https://doi.org/10.3390/geosciences11060240.

5. Riedel, M., T. Freudenthal, J. Bialas, C. Papenberg, M. Haeckel, M. Bergenthal, T. Pape, G. Bohrmann. 2021b. In-situ borehole temperature measurements confirm dynamics of the gas hydrate stability zone at the upper Danube deep sea fan, Black Sea. – Earth Planet. Sci. Lett., 563, 116869; https://doi.org/10.1016/j.epsl.2021.116869.