Amol Karandikar scite author profile

Amol Karandikar

2Publications

129Citation Statements Received

61Citation Statements Given

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113

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Affiliations

Carnegie Institution for Science, Geophysical Laboratory, Goethe University Frankfurt

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Melting of iron determined by X-ray absorption spectroscopy to 100 GPa

Aquilanti

Trapananti

Karandikar

et al. 2015

Proc. Natl. Acad. Sci. U.S.A.

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Temperature, thermal history, and dynamics of Earth rely critically on the knowledge of the melting temperature of iron at the pressure conditions of the inner core boundary (ICB) where the geotherm crosses the melting curve. The literature on this subject is overwhelming, and no consensus has been reached, with a very large disagreement of the order of 2,000 K for the ICB temperature. Here we report new data on the melting temperature of iron in a laser-heated diamond anvil cell to 103 GPa obtained by X-ray absorption spectroscopy, a technique rarely used at such conditions. The modifications of the onset of the absorption spectra are used as a reliable melting criterion regardless of the solid phase from which the solid to liquid transition takes place. Our results show a melting temperature of iron in agreement with most previous studies up to 100 GPa, namely of 3,090 K at 103 GPa.iron melting curve | XAS | megabar range

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Flash heating in the diamond cell: Melting curve of rhenium

Yang

Karandikar

Boehler

2012

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We have developed a multi-wavelength Fast Temperature Readout (FasTeR) spectrometer to capture a sample's transient temperature fluctuations, and reduce uncertainties in melting temperature determination. Without sacrificing accuracy, FasTeR features a fast readout rate (about 100 Hz), high sensitivity, large dynamic range, and a well-constrained focus. Complimenting a charge-coupled device spectrometer, FasTeR consists of an array of photomultiplier tubes and optical dichroic filters. The temperatures determined by FasTeR outside of the vicinity of melting are, generally, in good agreement with results from the charge-coupled device spectrometer. Near melting, FasTeR is capable of capturing transient temperature fluctuations, at least on the order of 300 K/s. A software tool, SIMFaster, is described and has been developed to simulate FasTeR and assess design configurations. FasTeR is especially suitable for temperature determinations that utilize ultra-fast techniques under extreme conditions. Working in parallel with the laser-heated diamond-anvil cell, synchrotron Mössbauer spectroscopy, and X-ray diffraction, we have applied the FasTeR spectrometer to measure the melting temperature of 57 Fe 0.9 Ni 0.1 at high pressure. C 2015 AIP Publishing LLC. [http://dx.

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Amol Karandikar

Melting of iron determined by X-ray absorption spectroscopy to 100 GPa

Flash heating in the diamond cell: Melting curve of rhenium

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