Simulation tools for atom probe tomography: A path for diagnosis and treatment of image degradation

Vurpillot, F.; Parviainen, S.; Djurabekova, Flyura; Zanuttini, David; Gervais, B.

doi:10.1016/j.matchar.2018.04.024

Cited by 16 publications

(16 citation statements)

References 47 publications

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“…It is counterintuitive that a void, which is essentially empty space, can exhibit an increased local atomic density region at the void position in the APT reconstruction. Simulated APT experiments provide a unique approach to gain insight on how the field-evaporation process is affected by the void's structure and surrounding composition 33 . Such simulations reproduce the gradual evolution of a virtual APT specimen by evaporating the tip atom-by-atom with an evaporation field assigned to each element comprising the material.…”

Section: Resultsmentioning

confidence: 99%

Interpreting nanovoids in atom probe tomography data for accurate local compositional measurements

et al. 2020

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Quantifying chemical compositions around nanovoids is a fundamental task for research and development of various materials. Atom probe tomography (APT) and scanning transmission electron microscopy (STEM) are currently the most suitable tools because of their ability to probe materials at the nanoscale. Both techniques have limitations, particularly APT, because of insufficient understanding of void imaging. Here, we employ a correlative APT and STEM approach to investigate the APT imaging process and reveal that voids can lead to either an increase or a decrease in local atomic densities in the APT reconstruction. Simulated APT experiments demonstrate the local density variations near voids are controlled by the unique ring structures as voids open and the different evaporation fields of the surrounding atoms. We provide a general approach for quantifying chemical segregations near voids within an APT dataset, in which the composition can be directly determined with a higher accuracy than STEM-based techniques.

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Section: Resultsmentioning

confidence: 99%

Interpreting nanovoids in atom probe tomography data for accurate local compositional measurements

et al. 2020

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“…At this point, no algorithm is published that would allow for the knowledge about the field evaporation artifacts to be included into the reconstruction at the scale of the datasets presented here. However, correlative 3D microscopy, combined with recently published field evaporation simulations based on full‐scale models may allow for the implementation of already published approaches for smaller scale corrections in a self‐consistent manner in the near future. We therefore directly used the 3D data from the atom probe for the atomistic simulations as a first approach, accounting for the discrepancies (see Section ).…”

Section: Resultsmentioning

confidence: 99%

Combining Experiments and Atom Probe Tomography‐Informed Simulations on γ′ Precipitation Strengthening in the Polycrystalline Ni‐Base Superalloy A718Plus

et al. 2020

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The strength of superalloys is strongly influenced by γ′ precipitates, whose size and volume fraction which can be adjusted by heat treatments. According to classical precipitation strengthening models, an increasing precipitate diameter should lead to a transition from weak to strong coupling of the dislocation pairs that form superdislocations in the γ′ phase. We show that long‐term annealing of the Ni‐base superalloy A718Plus at 670 and 680 °C increases the alloy's strength without significantly changing the grain size and η fraction. To understand the effect of the slight increase in γ′ size, detailed atom probe tomography (APT) was performed. Here, different field evaporation rates of the phases strongly affect the determination of the volume fraction when using the usual isosurface construction. This can be mitigated by considering the number density of atoms inside and outside the γ′ precipitates. Using an approximation of the precipitate shapes and arrangements from the APT data in atomistic simulations revealed that precipitate shearing by both, weakly and strongly coupled dislocations can occur in the same sample due to the wide distribution of precipitate sizes. These results highlight the need for advanced strengthening models that take into account the γ′ size distribution.

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“…A direct application of this method can be reasonably considered in the case of "real" nanoparticles such as enriched Co nanoparticles, Co/MnO x [47], and nanoalloys, CoCu [51]. Finally, it is important to notice that even if the oxygen exposure is performed in absence of electric field, the precise mechanism of field evaporation remains widely unknown and is still a matter of discussion within the APM community [52]. For the Co oxidation case, an additional investigation will be necessary to determine the influence of the electric field and the laser energy on the nature of the ions detected [53].…”

Section: Cobalt Oxidationmentioning

confidence: 99%

Nanoscale Perspectives of Metal Degradation via In Situ Atom Probe Tomography

et al. 2020

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We report a unique in situ instrument development effort dedicated to studying gas/solid interactions relevant to heterogeneous catalysis and early stages of oxidation of materials via atom probe tomography and microscopy (APM). An in situ reactor cell, similar in concept to other reports, has been developed to expose nanoscale volumes of material to reactive gas environments, in which temperature, pressure, and gas chemistry are well controlled. We demonstrate that the combination of this reactor cell with APM techniques can aid in building a better mechanistic understanding of resultant composition and surface and subsurface structure changes accompanying gas/surface reactions in metal and metal alloy systems through a series of case studies: O2/Rh, O2/Co, and O2/Zircaloy-4. In addition, the basis of a novel operando mode of analysis within an atom probe instrument is also reported. The work presented here supports the implementation of APM techniques dedicated to atomic to near-atomically resolved gas/surface interaction studies of materials broadly relevant to heterogeneous catalysis and oxidation.

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Simulation tools for atom probe tomography: A path for diagnosis and treatment of image degradation

Cited by 16 publications

References 47 publications

Interpreting nanovoids in atom probe tomography data for accurate local compositional measurements

Interpreting nanovoids in atom probe tomography data for accurate local compositional measurements

Combining Experiments and Atom Probe Tomography‐Informed Simulations on γ′ Precipitation Strengthening in the Polycrystalline Ni‐Base Superalloy A718Plus

Nanoscale Perspectives of Metal Degradation via In Situ Atom Probe Tomography

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