AUTHOR=Ijiri Akira , Setoguchi Ryoma , Mitsutome Yuki , Toki Tomohiro , Murayama Masafumi , Hagino Kyoko , Hamada Yohei , Yamagata Takeyasu , Matsuzaki Hiroyuki , Tanikawa Wataru , Tadai Osamu , Kitada Kazuya , Hoshino Tatsuhiko , Noguchi Takuro , Ashi Juichiro , Inagaki Fumio 

TITLE=Origins of sediments and fluids in submarine mud volcanoes off Tanegashima Island, northern Ryukyu Trench, Japan

JOURNAL=Frontiers in Earth Science

VOLUME=11

YEAR=2023

URL=https://www.frontiersin.org/journals/earth-science/articles/10.3389/feart.2023.1206810

DOI=10.3389/feart.2023.1206810

ISSN=2296-6463

ABSTRACT=<p>Mud volcanoes are topographic features through which over-pressurized sediments are intruded upward and erupted, transporting fluids and sediments from the deep subsurface to the surface/seafloor. To understand material and biogeochemical cycling through mud volcanoes, we investigated the origins of sediments and fluids erupted by four submarine mud volcanoes off Tanegashima Island, along the northern Ryukyu Trench: MV#1–3 and MV#14. We estimated the ages of the source sequences of the mud volcano sediments to be middle to late Miocene based on nannofossils and <sup>10</sup>Be ages. The sediments were characteristically enriched in illite. The similar mineral compositions and vitrinite reflectance values (0.42%–0.45%) of sediments erupted by the mud volcanoes strongly suggest that each is rooted in the same source sequence. Pore waters had Cl<sup>−</sup> concentrations ∼40% that of seawater and were proportionally enriched in <sup>18</sup>O and depleted in D, indicating the addition of freshwater from the dehydration of clay minerals. However, the smectite and illite contents (&lt;40%) in the clay size fraction ruled out <italic>in situ</italic> smectite dewatering as the cause of the pore water Cl<sup>−</sup> dilution. Thus, fluids derived from clay dewatering must have originated from deeper than the source sequence of the mud volcano sediments. Vertical Cl<sup>−</sup> profiles indicate that the upward fluid advection rate and eruption frequency decrease from MV#3 to MV#2, MV#1, and MV#14 (MV#14 being dormant). At the active mud volcanoes, the C<sub>1</sub>/C<sub>2</sub> ratios (&lt;100) and methane δ<sup>13</sup>C values (−56‰ to −42‰) indicate that hydrocarbon gases are mostly derived from the thermal decomposition of organic matter in deep sediments where the <italic>in situ</italic> temperature exceeds 80°C. At the dormant MV#14, high C<sub>1</sub>/C<sub>2</sub> ratios (700–4,000) and low methane δ<sup>13</sup>C values (ca. −75‰) suggest the limited supply of thermogenic methane and the subsequent shallow methanogenesis. Because vitrinite reflectance values indicate that the source sediments are too immature to produce thermogenic hydrocarbons, the hydrocarbon gases, like the fluids derived from clay dewatering, were probably supplied from deeper than the source strata. The supply of deep fluids into the source sequence might be a universal phenomenon in subduction zones, and may play an important role in mud volcanism and associated biogeochemical cycling.</p>