Defining the Potential of Nanoscale Re‐Os Isotope Systematics Using Atom Probe Microscopy

Daly, Luke; Bland, P. A.; Tessalina, Svetlana; Saxey, David W.; Reddy, Steven M.; Fougerouse, Denis; Rickard, William D.A.; Forman, L. V.; Fontaine, Alexandre; Cairney, Julie M.; Ringer, Simon P.; Schaefer, Bruce F.; Schwander, D.

doi:10.1111/ggr.12216

Cited by 16 publications

(14 citation statements)

References 70 publications

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“…Several recent studies have compared APT compositional results from geological samples with those from other geoanalytical techniques (Pérez‐Huerta et al , Daly et al , Exertier et al , Reinhard et al , Saxey et al ). Most comparisons provide excellent agreement, within the uncertainty arising from counting statistics in the atom probe data.…”

Section: Performance and Optimisationsmentioning

confidence: 99%

“…The atom probe provides a unique tool for investigating the nanoscale isotopic composition of minerals. Benchmarking of atom probe analysis of U isotopes in certified U 3 O 8 reference materials has shown that major isotopic ratios agree with known compositional values (Fahey et al ) and there are comparative thermal ion mass spectrometry (TIMS) and atom probe studies that show that Re‐Os analysis by atom probe may yield similar, though less precise, ages to more traditional TIMS analyses (Daly et al ). A number of studies have also investigated the mechanisms that can affect the distribution of radiogenic 207 Pb/ 206 Pb ratios in zircon (Figure ; Valley et al , , Peterman et al , Blum et al ), baddeleyite (White et al , Moser et al ) and monazite (Fougerouse et al , Seydoux‐Guillaume et al ).…”

Section: Geoscience Applicationsmentioning

confidence: 99%

“…Since the development of laser‐assisted APT, there has been growing interest in applying nanoscale geochemical characterisation to a broad range of geological materials including glass (Gin et al , Hellmann et al , Gin et al ), diamond (Heck et al , Lewis et al , Schirhagl et al , Mukherjee et al ), Fe‐Ni metal alloys (Einsle et al ) and silicides (Gopon et al ), platinum‐group alloys (Parman et al , Daly et al , ), oxides (Bachhav et al , , Fahey et al , Taylor et al , Frierdich et al , Gamal El Dien et al , Genareau et al , Taylor et al ), carbonates (Felmy et al , Branson et al , Pérez‐Huerta et al , Pérez‐Huerta and Laiginhas ), sulfides (Fougerouse et al , Dubosq et al , Fougerouse et al , Gopon et al , Wu et al ), sulfates (Weber et al ), zeolites (Schmidt et al ) and rock‐forming silicates, such as feldspars (White et al , Cao et al ) and olivine (Bloch et al , Cukjati et al , Figure ). However, a high proportion of the published APT work to date has focussed on trace element mobility, particularly Pb, in accessory minerals.…”

Section: Geoscience Applicationsmentioning

confidence: 99%

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Atom Probe Tomography: Development and Application to the Geosciences

Reddy

Saxey

Rickard

et al. 2020

Geostandard Geoanalytic Res

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Atom probe tomography (APT) is an analytical technique that provides quantitative three‐dimensional elemental and isotopic analyses at sub‐nanometre resolution across the whole periodic table. Although developed and mostly used in the materials science and semiconductor fields, recent years have seen increasing development and application in the geoscience and planetary science disciplines. Atom probe studies demonstrate compositional complexity at the nanoscale and provide fundamental new insights into the atom‐scale mechanisms taking place in minerals over geological time. Here, we provide an overview of APT, including the historical development and technical aspects of the instrumentation, and the fundamentals of data acquisition, data processing and data reconstruction. We also review previous studies and highlight the potential future applications of nanoscale geochemical studies of natural materials.

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Section: Performance and Optimisationsmentioning

confidence: 99%

Section: Geoscience Applicationsmentioning

confidence: 99%

Section: Geoscience Applicationsmentioning

confidence: 99%

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Atom Probe Tomography: Development and Application to the Geosciences

Reddy

Saxey

Rickard

et al. 2020

Geostandard Geoanalytic Res

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“…Application of APM to radiogenic isotope geochemistry has been demonstrated using the U-Pb system [8 10]. And other radiogenic systems, such as Sm-Nd and Re-Os, also appear amenable to the technique, where concentrations permit [72]. Within this field, the atom probe is an ideal tool for determining the origin and history of geological materials from sub-micron isotopic signatures, which are often not resolvable using other techniques.…”

Section: Isotopic Analysis: Tracers and Chronometersmentioning

confidence: 99%

Atomic worlds: Current state and future of atom probe tomography in geoscience

et al. 2018

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Atom Probe Microscopy (APM) is rapidly finding new applications within the geosciences. Historically connected with materials science and semiconductor device applications, recent years have seen an exciting trend as APM has proved a useful tool for nanoscale geochemistry, as it offers unique capabilities when compared with the current suite of conventional geoanalytical techniques. The ability to characterize 3D nanoscale chemistry with isotopic sensitivity, and correlate these results with other analytical techniques, has uncovered intricate details of complex trace element distributions within a variety of minerals and has opened the door to nanoscale isotope geochemistry. Already these advances are having an impact on long-standing questions within geochronology, planetary science and many other fields of research. As this trend gathers pace, we present here a brief summary of the current status of APM geoscience applications and discuss the likely future directions in this developing research space.

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“… Daly et al (2017b) performed APM analyses of sub-micrometer PGE-rich refractory metal nuggets contained within a Sc-Zr–rich ultrarefractory inclusion from the ALH 77307 CO3.0 meteorite. More recently, Daly et al (2018) employed the laser-assisted APM technique to measure Re and Os isotope ratios of pure Os, pure Re, and synthetic Re-Os-bearing alloys, demonstrating that the APM technique permits nanoscale Os isotope ratio measurements of Os-bearing alloys to yield similar, though less precise, ages to NTIMS analyses. At current, development and application of the analytically expensive and highly-specific APM technique in geosciences is still in its early stages ( Reddy et al, 2020 ).…”

Section: In-situ Techniques For Os Isotope Ratio and Re Pgementioning

confidence: 99%

Analytical Methods for Os Isotope Ratios and Re-PGE Mass Fractions in Geological Samples

Chu

2021

Front. Chem.

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The recent advances in analytical methods of Re-Os and PGE in geological materials including sample dissolution, chemical separation, mass spectrometric determinations, as well as the developments of matrix-matched reference materials for data quality control are thoroughly reviewed. Further, the in-situ measurement methods for Re-PGE mass fractions and 187Os/188Os ratios, as well as the measurement methods for stable isotope ratios of Re and PGE are also briefly reviewed. This review stands as a comprehensive reference for researchers to consider in the development of measurement methods for Re-PGE mass fractions and 187Os/188Os ratios in geological materials.

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Defining the Potential of Nanoscale Re‐Os Isotope Systematics Using Atom Probe Microscopy

Cited by 16 publications

References 70 publications

Atom Probe Tomography: Development and Application to the Geosciences

Atom Probe Tomography: Development and Application to the Geosciences

Atomic worlds: Current state and future of atom probe tomography in geoscience

Analytical Methods for Os Isotope Ratios and Re-PGE Mass Fractions in Geological Samples

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