Paul D. Asimow scite author profile

International audienceSeveral methods have been developed to assess the thermal state of the mantle below oceanic ridges, islands, and plateaus, on the basis of the petrology and geochemistry of erupted lavas. One leads to the conclusion that mantle potential temperature (i.e., TP) of ambient mantle below oceanic ridges is 1430°C, the same as Hawaii. Another has ridges with a large range in ambient mantle potential temperature (i.e., TP = 1300–1570°C), comparable in some cases to hot spots (Klein and Langmuir, 1987; Langmuir et al., 1992). A third has uniformly low temperatures for ambient mantle below ridges, ∼1300°C, with localized 250°C anomalies associated with mantle plumes. All methods involve assumptions and uncertainties that we critically evaluate. A new evaluation is made of parental magma compositions that would crystallize olivines with the maximum forsterite contents observed in lava flows. These are generally in good agreement with primary magma compositions calculated using the mass balance method of Herzberg and O'Hara (2002), and differences reflect the well-known effects of fractional crystallization. Results of primary magma compositions we obtain for mid-ocean ridge basalts and various oceanic islands and plateaus generally favor the third type of model but with ambient mantle potential temperatures in the range 1280–1400°C and thermal anomalies that can be 200–300°C above this background. Our results are consistent with the plume model

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Petrology of some oceanic island basalts: PRIMELT2.XLS software for primary magma calculation

Herzberg

Asimow²

2008

Geochem Geophys Geosyst

448

411

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[1] PRIMELT2.XLS software is introduced for calculating primary magma composition and mantle potential temperature (T P ) from an observed lava composition. It is an upgrade over a previous version in that it includes garnet peridotite melting and it detects complexities that can lead to overestimates in T P by >100°C. These are variations in source lithology, source volatile content, source oxidation state, and clinopyroxene fractionation. Nevertheless, application of PRIMELT2.XLS to lavas from a wide range of oceanic islands reveals no evidence that volatile-enrichment and source fertility are sufficient to produce them. All are associated with thermal anomalies, and this appears to be a prerequisite for their formation. For the ocean islands considered in this work, T P maxima are typically $1450-1500°C in the Atlantic and 1500-1600°C in the Pacific, substantially greater than $1350°C for ambient mantle. Lavas from the Galápagos Islands and Hawaii record in their geochemistry high T P maxima and large ranges in both T P and melt fraction over short horizontal distances, a result that is predicted by the mantle plume model.

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Algorithmic modifications extending MELTS to calculate subsolidus phase relations

Asimow

Ghiorso

1998

American Mineralogist

671

372

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The importance of water to oceanic mantle melting regimes

Asimow

Langmuir

2003

Nature

358

270

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The formation of basaltic crust at mid-ocean ridges and ocean islands provides a window into the compositional and thermal state of the Earth's upper mantle. But the interpretation of geochemical and crustal-thickness data in terms of magma source parameters depends on our understanding of the melting, melt-extraction and differentiation processes that intervene between the magma source and the crust. Much of the quantitative theory developed to model these processes has neglected the role of water in the mantle and in magma, despite the observed presence of water in ocean-floor basalts. Here we extend two quantitative models of ridge melting, mixing and fractionation to show that the addition of water can cause an increase in total melt production and crustal thickness while causing a decrease in mean extent of melting. This may help to resolve several enigmatic observations in the major- and trace-element chemistry of both normal and hotspot-affected ridge basalts.

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Adiabat_1ph: A new public front‐end to the MELTS, pMELTS, and pHMELTS models

Smith

Asimow

2005

Geochem Geophys Geosyst

450

279

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The program adiabat_1ph is a simple text‐menu driver for subroutine versions of the algorithms MELTS, pMELTS, and pHMELTS [Asimow et al., 2004; Ghiorso et al., 2002; Ghiorso and Sack, 1995]. It may be used to calculate equilibrium assemblages along a thermodynamic path set by the user and can simultaneously calculate trace element distributions. The MELTS family of algorithms is suitable for multicomponent systems, which may be anhydrous, water‐undersaturated, or water‐saturated, with the options of buffering oxygen fugacity and/or water activity. A wide variety of calculations can be performed either subsolidus or with liquid(s) present; melting and crystallization may be batch, fractional, or continuous. The software is suitable for Linux, MacOS X, and Windows, and many aspects of program execution are controlled by environment variables. Perl scripts are also provided that may be used to invoke adiabat_1ph with some command line options and to produce output that may be easily imported into spreadsheet programs, such as Microsoft Excel. Benefits include a batch mode, which allows almost complete automation of the calculation process when suitable input files are written. This technical brief describes version 1.04, which is provided as . Binaries, scripts, documentation, and example files for this and future releases may be downloaded at http://www.gps.caltech.edu/~asimow/adiabat. On a networked computer, adiabat_1ph automatically checks whether a newer version is available.

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Paul D. Asimow

Temperatures in ambient mantle and plumes: Constraints from basalts, picrites, and komatiites

Petrology of some oceanic island basalts: PRIMELT2.XLS software for primary magma calculation

Algorithmic modifications extending MELTS to calculate subsolidus phase relations

The importance of water to oceanic mantle melting regimes

Adiabat_1ph: A new public front‐end to the MELTS, pMELTS, and pHMELTS models

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