An experimental study on smectites as nitrogen conveyors in subduction zones

Cedeño, Daniel Grings; Conceição, Rômmulo Vieira; Souza, Márcio Roberto Wilbert de; Quinteiro, R.V.S.; Carniel, Larissa Colombo; Ketzer, João Marcelo Medina; Rodrigues, F; Bruzza, Eduardo do Canto

doi:10.1016/j.clay.2018.11.006

Cited by 8 publications

(6 citation statements)

References 31 publications

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“…In the geological cycle of nitrogen, the initial source introduced into the subduction zone is organic material deposited in seafloor sediments (Bebout et al, 2013). During diagenesis and low‐grade metamorphic evolution, nitrogen is released into pore fluids as ammonia (NH 3 ) then transforms into the form of ammonium (NH 4 + ) (Busigny & Bebout, 2013; Cedeño et al, 2019). Having similar charge and ionic radius, the released NH 4 + ion acts as an ideal substitution for K + in such phyllosilicates as clay minerals and micas, and alkali feldspars, confirmed by strong correlation between concentration of nitrogen and LIL elements, such as K, Rb and Cs (Busigny et al, 2003; Halama et al, 2010).…”

Section: Discussionmentioning

confidence: 99%

“…Having similar charge and ionic radius, the released NH 4 + ion acts as an ideal substitution for K + in such phyllosilicates as clay minerals and micas, and alkali feldspars, confirmed by strong correlation between concentration of nitrogen and LIL elements, such as K, Rb and Cs (Busigny et al, 2003; Halama et al, 2010). The breakdown of micas during prograde metamorphism results in a continuous release of NH 4 + , although high stability of NH 4 + under HP in white micas (phengite) or K‐feldspar (hollandite) allows its retention to great depths (even of the transition zone) depending on redox conditions (Bebout, 2007; Cedeño et al, 2019; Watenphul et al, 2009). Efficiency of nitrogen release, which would equilibrate as N 2 (Li & Keppler, 2014), is mostly controlled by the breakdown of phengite, which is showing a strong correlation with the thermal gradient of subduction zones (Mitchell et al, 2010).…”

Section: Discussionmentioning

confidence: 99%

“…Efficiency of nitrogen release, which would equilibrate as N 2 (Li & Keppler, 2014), is mostly controlled by the breakdown of phengite, which is showing a strong correlation with the thermal gradient of subduction zones (Mitchell et al, 2010). Consequently, hot subduction paths promote a high degree of N escape, whereas cold geotherms enable the retention of NH 4 + in HP micas or clay minerals resulting in efficient transport of nitrogen into great depths (Cedeño et al, 2019). Previous studies of Ábalos et al (2003) and Puelles et al (2005) highlighted that the studied suites of HP subducted rocks of the COC have been involved in prograde metamorphic evolution following a warm subduction PT path with 13–14°C/km, which would be sufficient for elevated N 2 release (Busigny & Bebout, 2013).…”

Section: Discussionmentioning

confidence: 99%

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Abiotic passive nitrogen and methane enrichment during exhumation of subducted rocks: Primary multiphase fluid inclusions in high‐pressure rocks from the Cabo Ortegal Complex, NW Spain

Spránitz

Padrón‐Navarta

Szabó

et al. 2022

Journal Metamorphic Geology

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Primary multiphase fluid inclusions (MFI) were studied in one eclogite and two granulites from the Cabo Ortegal Complex (COC, NW Spain) by means of Raman imaging, Scanning Electron Microscopy with Energy Dispersive Spectroscopy (SEM‐EDS) and Focused Ion Beam ‐ Scanning Electron Microscopy (FIB)‐SEM. Complementary, secondary MFI in pyroxenites from COC were also investigated. MFI hosted in eclogite and granulites occur along growth zones or in 3D clusters in garnet porphyroblasts suggesting a primary origin at high‐pressure (HP) metamorphic conditions. The mineral assemblage of MFI is mainly composed of Fe‐Mg‐Ca‐carbonates and phyllosilicates ± graphite ± quartz ± corundum ± pyrite ± apatite ± rutile and a fluid phase composed of nitrogen ± methane ± carbon‐dioxide. The mineral proportions vary among the lithologies. Dominant carbonates and hydrous silicates are interpreted as step‐daughter minerals (crystals formed in the MFI after entrapment as a result of fluid–host interaction), whereas apatite, quartz and rutile are considered in part as accidentally trapped minerals since they also occur as crystal inclusions together with MFI in each rock type. Quartz and corundum occur together in MFI in ultramafic granulite and are regarded as step‐daughter minerals in this lithology. These observations suggest that the MFI are products of post‐entrapment reactions of a homogeneous COHN fluid system with the host mineral. Thermodynamic calculations in the CaFMAS‐COHN system confirmed that bulk composition of the MFI in eclogite is similar to the host garnet+COHN composition except for a potential lost of H2O. Carbonation and hydration reaction between the host (i.e. garnet or pyroxene) and the fluid inclusion results in the consumption of all CO2 and part of the H2O from the fluid phase producing Ca‐Fe‐Mg‐carbonates and hydrous step‐daughter minerals, mostly pyrophyllite and chlorite. Nitrogen content of the originally trapped COHN fluid in eclogite was estimated to have a maximum value of 10 mol% at peak HP conditions and 30–40 mol% at retrograde conditions that is within the range of the observed MFI in the residual fluid (13–68 mol%). Pseudosection modelling confirmed the stability of the phase assemblage in the MFI in a specific low‐pressure, low‐temperature stability field (between 300°C and 400°C at pressures < 1 GPa), caused by H2O‐ and CO2‐consuming reactions possibly in a single step. Our findings indicate that such processes in the exhuming HP units may play a role in global nitrogen and carbon cycling as well as potentially contributing to nitrogen and methane supply to subsurface–surface environments during devolatilization in the forearc regions of convergent plate margins.

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Section: Discussionmentioning

confidence: 99%

Section: Discussionmentioning

confidence: 99%

Section: Discussionmentioning

confidence: 99%

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Abiotic passive nitrogen and methane enrichment during exhumation of subducted rocks: Primary multiphase fluid inclusions in high‐pressure rocks from the Cabo Ortegal Complex, NW Spain

Spránitz

Padrón‐Navarta

Szabó

et al. 2022

Journal Metamorphic Geology

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“…Global models provided the suggestion that aqueous fluids and hydrous melts produced enhanced chemical recycling particularly in hot subduction zones (Hernández-Uribe et al, 2019). Applications to specific elemental or isotopic systems include that of Ce and Nd under the Mariana volcanic arc (Bellot et al, 2018) and the determination that nitrogen subduction in clay minerals is only possible in cold subduction zones (Cedeño et al, 2019). Slab surface temperatures strongly correlate with Mg-isotope ratios observed in volcanic arcs confirming a thermal control on processes controlling Mg release from the subducting slab (Hu et al, 2020).…”

Section: Interpretation Of Geochemistrymentioning

confidence: 99%

An introductory review of the thermal structure of subduction zones: I. Motivation and selected examples

Keken¹,

Wilson

2023

Preprint

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The thermal structure of subduction zones is fundamental to our understanding of physical and chemical processes that occur at active convergent plate margins. These include magma generation and related arc volcanism, shallow and deep seismicity, and metamorphic reactions that can release fluids. Computational models can predict the thermal structure to great numerical precision when models are fully described but this does not guarantee accuracy or applicability. In a pair of companion papers the construction of thermal subduction zone models, their use in subduction zone studies, and their link to geophysical and geochemical observations is explored. In part I the motivation to understand the thermal structure is presented based on experimental and observational studies. This is followed by a description of a selection of thermal models for the Japanese subduction zones.

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“…Global models provided the suggestion that aqueous fluids and hydrous melts produced enhanced chemical recycling particularly in hot subduction zones (Hernández-Uribe et al, 2019). Applications to specific elemental or isotopic systems include those of Ce and Nd under the Mariana volcanic arc (Bellot et al, 2018) and the determination that nitrogen subduction in clay minerals is only possible in cold subduction zones (Cedeño et al, 2019). Slab surface temperatures strongly correlate with Mg isotope ratios observed in volcanic arcs confirming a thermal control on processes controlling Mg release from the subducting slab (Hu et al, 2020).…”

Section: Interpretation Of Geochemistrymentioning

confidence: 99%

An introductory review of the thermal structure of subduction zones: I. Motivation and selected examples

Keken¹

2023

Preprint

View full text Add to dashboard Cite

show abstract

An experimental study on smectites as nitrogen conveyors in subduction zones

Cited by 8 publications

References 31 publications

Abiotic passive nitrogen and methane enrichment during exhumation of subducted rocks: Primary multiphase fluid inclusions in high‐pressure rocks from the Cabo Ortegal Complex, NW Spain

Abiotic passive nitrogen and methane enrichment during exhumation of subducted rocks: Primary multiphase fluid inclusions in high‐pressure rocks from the Cabo Ortegal Complex, NW Spain

An introductory review of the thermal structure of subduction zones: I. Motivation and selected examples

An introductory review of the thermal structure of subduction zones: I. Motivation and selected examples

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