Magma Redox Geochemistry. Группа авторов
Чтение книги онлайн.

Читать онлайн книгу Magma Redox Geochemistry - Группа авторов страница 38

Название: Magma Redox Geochemistry

Автор: Группа авторов

Издательство: John Wiley & Sons Limited

Жанр: Физика

Серия:

isbn: 9781119473244

isbn:

СКАЧАТЬ recorded by volcanics globally in different tectonic settings and by multiple methods of oxybarometry. We have recalculated the fO2 recorded by each sample based on the reported chemical analyses except for the separate light gray dataset in panel (a), which are the observations as reported by O’Neill et al. (2018). The O’Neill et al. (2018) dataset was collected using a different set of primary standards, as described in our methods appendix. Vertical, dashed lines reflect calculated average values of fO2. Note that volcanics in (e) include plume‐affected ridge segments, which cause them to record bimodal fO2; the fO2s inferred for primitive plume magmas are higher than the average and we represent each plume’s primitive magma fO2 as a filled orange circle (as reported by those authors). See Table 3.1 and text for details.

Schematic illustration of distribution of fO2 recorded by mantle lithologies (peridotites and olivine-orthopyroxene-spinel bearing pyroxenites) globally in different tectonic settings.

      We highlight that peridotites along SWIR record five times greater range in fO2 when compared to basalts dredged from the same segment. On the global scale, Bryndzia and Wood (1990) investigated the fO2 of 35 ridge peridotites from 12 localities. When filtered to exclude four samples from two anomalous locations (the sub‐aerial St. Paul’s Rocks and the tectonically complex Mid‐Cayman Rise), and recalculated according to the methods presented here, this sample set records fO2 of QFM ‐0.08 ±0.68 and spans a range of nearly 2.5 orders of magnitude in fO2 (Birner et al., 2018). When comparing Fig. 3.2a and 3.3a, we observe that global mid‐ocean ridge volcanics display low variance relative to ridge peridotites. These limited data suggest that basalts may homogenize kilometer‐scale redox heterogeneity in the upper mantle (Birner et al., 2018). Globally, ridge peridotites calculated at 0.6 GPa and the temperature of olivine‐spinel closure record average fO2s about half a log unit higher than basalts calculated at 1 bar and 1200 °C. Because we have not attempted here to account for subsolidus processes in the peridotites globally, comparisons between the two distributions should not be overinterpreted. A more comprehensive global peridotite dataset is required to evaluate the response of mantle residues to melt extraction and subsolidus re‐equilibration.

       Arcs and Back Arcs.

      Subduction influences the composition of mantle melts and arc volcanics, generating continental crust in the process (e.g., Elliott et al., 1997; Gill, 1981; Grove et al., 2012; Kelemen et al., 2003; Kelemen et al., 2007; Osborn, 1959; Plank & Langmuir, 1988; Stolper & Newman, 1994; Turner & Langmuir, 2015; Zimmer et al., 2010). Both melts and mantle lithologies offer opportunities for oxybarometry. We begin with the volcanics.

      Seminal contributions by Carmichael (1991) and Frost and Lindsley (1992) surveyed the fO2s recorded by arc rocks using wet‐chemistry and magnetite‐ilmenite pairs, respectively, and found that arc rocks record fO2s up to several orders of magnitude higher than MORBs. Our compilation of 5 XANES spectroscopic studies (n=119 samples, Figure 3.2c) of olivine‐hosted melt inclusions and submarine pillow glasses shows that arc basalts record, on average, QFM +0.96 (±0.39). One set of outliers from Cerro Negro record QFM +4.75 (±0.40) (Gaetani et al., 2012), but spectra from these hydrous samples have suffered from radiation‐induced beam damage (Cottrell et al., 2018, Gaetani, pers. comm.) and are not included in our statistical analysis. Nearly 90% of samples with XANES measurements erupted through the thin crust (~25 km, Takahashi et al., 2007) of the active Mariana arc front (Fig. 3.1a), and thus there is significant location bias in this dataset.

      Globally, magnetite–ilmenite pairs, from 114 arc lavas sampling 11 different arcs, record QFM +1.28 (±0.64) (Figure 3.2d; see methods appendix and the online data library associated with this contribution, Cottrell et al., 2021, for citations). These samples contain Fe–Ti oxides with compositions that record a range of temperatures (700–1085 °C), span a wide range of compositions (basaltic andesite to rhyolite) but are predominantly dacitic, and erupt through crust ranging from 25 to 66km thick.

      The mean fO2 recorded by olivine‐hosted melt inclusions and submarine arc‐front glasses (ΔQFM = 0.96±0.39, n=119) is slightly lower than that recorded by magnetite‐ilmenite pairs (ΔQFM = 1.28±0.64 n=114) at the 95% confidence level (tstatistic = 4.6, tcritical = 2.0, degrees of freedom [DF] = 186, p‐value < 0.001). (When we compare distribution means in this contribution, we will always apply a two‐sample student’s t‐test with α= 0.05 [Krzywinski & Altman, 2013] for samples of unequal variance.) We caution СКАЧАТЬ