Your search keyword '"Gault B"' showing total 22 results

1. Coherent solvus of disordered alkali feldspar: experiment, atom probe tomography and thermodynamic model

Author

Heuser, D., Dubosq, R., Petrishcheva, E., Bian, G., Rentenberger, C., Lengauer, C. L., Gault, B., Habler, G., Abart, R., Heuser, D., Dubosq, R., Petrishcheva, E., Bian, G., Rentenberger, C., Lengauer, C. L., Gault, B., Habler, G., and Abart, R.

Abstract

At temperatures above about 600 °C, alkali feldspar forms a continuous solid solution between the Na and K end members. Towards lower temperatures a miscibility gap opens, and alkali feldspar of intermediate composition exsolves, forming an intergrowth of relatively more Na-rich and K-rich lamellae. During exsolution, the crystal structure usually remains coherent across the lamellar interfaces, a feature that may be preserved over geological times. Due to the compositional dependence of the lattice parameters, coherent intergrowth requires that the lamellae are elastically strained. The associated elastic strain energy counteracts exsolution, and the solvus delimiting the misciblity gap for coherent intergrowth lies below the solvus for strain free phase equilibria. To determine the coherent solvus, homogeneous gem quality alkali feldspar of intermediate composition was annealed at conditions falling into the two-phase region of the phase diagram. Thereby a coherent intergrowth of approximately 10–20 nanometers wide lamellae was produced. Lamellar compositions were determined with atom probe tomography defining points on the coherent solvus. In parallel, the coherent solvus was calculated using a thermodynamic mixing model calibrated on the same alkali feldspar as used for the exsolution experiments and accounting for the elastic strain energy associated with coherent lamellar intergrwoth. The experimentally determined and the calculated coherent solvus are in excellent agreement indicating that phase equilibria in coherent lamellar intergrowth of alkali feldspar are adequately described, providing a sound basis for the interpretation of phase relations in coherently exsolved alkali feldspar.

Published

2024

2. Atom probe tomography analysis of the reference zircon gj-1: An interlaboratory study

Author

Exertier, F., La Fontaine, A., Corcoran, C., Piazolo, S., Belousova, E., Peng, Z., Gault, B., Saxey, David, Fougerouse, Denis, Reddy, Steven, Pedrazzini, S., Bagot, P., Moody, M., Langelier, B., Moser, D., Botton, G., Vogel, F., Thompson, G., Blanchard, P., Chiaramonti, A., Reinhard, D., Rice, K., Schreiber, D., Kruska, K., Wang, J., Cairney, J., Exertier, F., La Fontaine, A., Corcoran, C., Piazolo, S., Belousova, E., Peng, Z., Gault, B., Saxey, David, Fougerouse, Denis, Reddy, Steven, Pedrazzini, S., Bagot, P., Moody, M., Langelier, B., Moser, D., Botton, G., Vogel, F., Thompson, G., Blanchard, P., Chiaramonti, A., Reinhard, D., Rice, K., Schreiber, D., Kruska, K., Wang, J., and Cairney, J.

Abstract

In recent years, atom probe tomography (APT) has been increasingly used to study minerals, and in particular the mineral zircon. Zircon (ZrSiO4) is ideally suited for geochronology by utilising the U-Th-Pb isotope systems, and trace element compositions are also widely used to constrain petrogenetic processes. However, while standard geoanalytical techniques provide information at micrometer scale lengths, the unique combination of chemical/isotopic sensitivity and spatial resolution of APT allows compositional and textural measurements at the nanoscale. This interlaboratory study aims to define the reproducibility of APT data across research facilities and assess the role of different aspects of the atom probe workflow on reproducibility. This is essential to allow correct evaluation of APT results and full utilization of this emerging technique within the geoscience community. In this study, nine samples from the same homogeneous, GJ-1/87 zircon reference grain were sent to nine APT institutes in Germany, the UK, USA, Canada and Australia. After preparing the sample out of a selectioned slab, each institute conducted three different rounds of APT analyses: using (i) unconstrained analysis parameters, (ii) pre-defined analysis parameters, and (iii) interpreting and quantifying a provided dataset. Data such as the measured elemental composition, acquisition parameters, or mass spectrum peak identifications, were recorded and analyzed. We observe a significant variation in the measured composition across this interlaboratory study as well as the number of trace elements identified. These differences are thought to directly result from the user's choice of atom probe data analysis parameters. The type of instrument does not seem to be a critical factor. Consequently, comparison of absolute trace element concentrations on zircon using APT between laboratories is only valid if the same workflow has been ensured.

Published

2018

3. Nanoscale Stoichiometric Analysis of a High-Temperature Superconductor by Atom Probe Tomography

Author

Pedrazzini, S., London, A., Gault, B., Saxey, David, Speller, S., Grovenor, C., Danaie, M., Moody, M., Edmondson, P., Bagot1, P., Pedrazzini, S., London, A., Gault, B., Saxey, David, Speller, S., Grovenor, C., Danaie, M., Moody, M., Edmondson, P., and Bagot1, P.

Abstract

The functional properties of the high-temperature superconductor Y1Ba2Cu3O7−δ (Y-123) are closely correlated to the exact stoichiometry and oxygen content. Exceeding the critical value of 1 oxygen vacancy for every five unit cells (δ>0.2, which translates to a 1.5 at% deviation from the nominal oxygen stoichiometry of Y7.7Ba15.3Cu23O54−δ) is sufficient to alter the superconducting properties. Stoichiometry at the nanometer scale, particularly of oxygen and other lighter elements, is extremely difficult to quantify in complex functional ceramics by most currently available analytical techniques. The present study is an analysis and optimization of the experimental conditions required to quantify the local nanoscale stoichiometry of single crystal yttrium barium copper oxide (YBCO) samples in three dimensions by atom probe tomography (APT). APT analysis required systematic exploration of a wide range of data acquisition and processing conditions to calibrate the measurements. Laser pulse energy, ion identification, and the choice of range widths were all found to influence composition measurements. The final composition obtained from melt-grown crystals with optimized superconducting properties was Y7.9Ba10.4Cu24.4O57.2.

Published

2017

4. Behavior of molecules and molecular ions near a field emitter

Author

Gault, B., Saxey, David, Ashton, M., Sinnott, S., Chiaramonti, A., Moody, M., Schreiber, D., Gault, B., Saxey, David, Ashton, M., Sinnott, S., Chiaramonti, A., Moody, M., and Schreiber, D.

Abstract

The cold emission of particles from surfaces under intense electric fields is a process which underpins a variety of applications including atom probe tomography (APT), an analytical microscopy technique with near-atomic spatial resolution. Increasingly relying on fast laser pulsing to trigger the emission, APT experiments often incorporate the detection of molecular ions emitted from the specimen, in particular from covalently or ionically bonded materials. Notably, it has been proposed that neutral molecules can also be emitted during this process. However, this remains a contentious issue. To investigate the validity of this hypothesis, a careful review of the literature is combined with the development of new methods to treat experimental APT data, the modeling of ion trajectories, and the application of density-functional theory simulations to derive molecular ion energetics. It is shown that the direct thermal emission of neutral molecules is extremely unlikely. However, neutrals can still be formed in the course of an APT experiment by dissociation of metastable molecular ions.

Published

2016

5. From solid solution to cluster formation of Fe and Cr in α-Zr

Author

Burr, PA, Wenman, MR, Gault, B, Moody, MP, Ivermark, M, Rushton, MJD, Preuss, M, Edwards, L, Grimes, RW, Burr, PA, Wenman, MR, Gault, B, Moody, MP, Ivermark, M, Rushton, MJD, Preuss, M, Edwards, L, and Grimes, RW

Abstract

To understand the mechanisms by which the re-solution of Fe and Cr additions increase the corrosion rate of irradiated Zr alloys, the solubility and clustering of Fe and Cr in model binary Zr alloys was investigated using a combination of experimental and modelling techniques - atom probe tomography (APT), x-ray diffraction (XRD), thermoelectric power (TEP) and density functional theory (DFT). Cr occupies both interstitial and substitutional sites in the α-Zr lattice; Fe favours interstitial sites, and a low-symmetry site that was not previously modelled is found to be the most favourable for Fe. Lattice expansion as a function of Fe and Cr content in the α-Zr matrix deviates from Vegard's law and is strongly anisotropic for Fe additions, expanding the c-axis while contracting the a-axis. Matrix content of solutes cannot be reliably estimated from lattice parameter measurements, instead a combination of TEP and APT was employed. Defect clusters form at higher solution concentrations, which induce a smaller lattice strain compared to the dilute defects. In the presence of a Zr vacancy, all two-atom clusters are more soluble than individual point defects and as many as four Fe or three Cr atoms could be accommodated in a single Zr vacancy. The Zr vacancy is critical for the increased apparent solubility of defect clusters; the implications for irradiation induced microstructure changes in Zr alloys are discussed.

Published

2015

6. Interpreting atom probe data from chromium oxide scales

Author

La Fontaine, A, Gault, B, Breen, A, Stephenson, L, Ceguerra, AV, Yang, L, Dinh Nguyen, T, Zhang, J, Young, DJ, Cairney, JM, La Fontaine, A, Gault, B, Breen, A, Stephenson, L, Ceguerra, AV, Yang, L, Dinh Nguyen, T, Zhang, J, Young, DJ, and Cairney, JM

Abstract

Picosecond-pulsed ultraviolet-laser (UV-355 nm) assisted atom probe tomography (APT) was used to analyze protective, thermally grown chromium oxides formed on stainless steel. The influence of analysis parameters on the thermal tail observed in the mass spectra and the chemical composition is investigated. A new parameter termed "laser sensitivity factor" is introduced in order to quantify the effect of laser energy on the extent of the thermal tail. This parameter is used to compare the effect of increasing laser energy on thermal tails in chromia and chromite samples. Also explored is the effect of increasing laser energy on the measured oxygen content and the effect of specimen base temperature and laser pulse frequency on the mass spectrum. Finally, we report a preliminary analysis of molecular ion dissociations in chromia.

Published

2015

7. Atomically resolved tomography to directly inform simulations for structure-property relationships

Author

Moody,MP, Ceguerra,AV, Breen,AJ, Cui,XY, Gault,B, Stephenson,LT, Marceau,RK, Powles,RC, Ringer,SP, Moody,MP, Ceguerra,AV, Breen,AJ, Cui,XY, Gault,B, Stephenson,LT, Marceau,RK, Powles,RC, and Ringer,SP

Abstract

Microscopy encompasses a wide variety of forms and scales. So too does the array of simulation techniques developed that correlate to and build upon microstructural information. Nevertheless, a true nexus between microscopy and atomistic simulations is lacking. Atom probe has emerged as a potential means of achieving this goal. Atom probe generates three-dimensional atomistic images in a format almost identical to many atomistic simulations. However, this data is imperfect, preventing input into computational algorithms to predict material properties. Here we describe a methodology to overcome these limitations, based on a hybrid data format, blending atom probe and predictive Monte Carlo simulations. We create atomically complete and lattice-bound models of material specimens. This hybrid data can then be used as direct input into density functional theory simulations to calculate local energetics and elastic properties. This research demonstrates the role that atom probe combined with theoretical approaches can play in modern materials engineering.

Published

2014

8. On the roles of graphene oxide doping for enhanced supercurrent in MgB 2 based superconductors

Author

Yeoh, W K, Cui, X Y, Gault, B, De Silva, K S. B, Xu, X, Liu, H W, Yen, H. -W, Wong, D, Bao, P, Larson, D J, Martin, I, Li, W X, Zheng, R K, Wang, X L, Dou, S X, Ringer, S P, Yeoh, W K, Cui, X Y, Gault, B, De Silva, K S. B, Xu, X, Liu, H W, Yen, H. -W, Wong, D, Bao, P, Larson, D J, Martin, I, Li, W X, Zheng, R K, Wang, X L, Dou, S X, and Ringer, S P

Abstract

Due to their graphene-like properties after oxygen reduction, incorporation of graphene oxide (GO) sheets into correlated-electron materials offers a new pathway for tailoring their properties. Fabricating GO nanocomposites with polycrystalline MgB2 superconductors leads to an order of magnitude enhancement of the supercurrent at 5 K/8 T and 20 K/4 T. Herein, we introduce a novel experimental approach to overcome the formidable challenge of performing quantitative microscopy and microanalysis of such composites, so as to unveil how GO doping influences the structure and hence the material properties. Atom probe microscopy and electron microscopy were used to directly image the GO within the MgB2, and we combined these data with computational simulations to derive the property-enhancing mechanisms. Our results reveal synergetic effects of GO, namely, via localized atomic (carbon and oxygen) doping as well as texturing of the crystals, which provide both inter- and intra-granular flux pinning. This study opens up new insights into how low-dimensional nanostructures can be integrated into composites to modify the overall properties, using a methodology amenable to a wide range of applications.

Published

2014

9. On the roles of graphene oxide doping for enhanced supercurrent in MgB 2 based superconductors

Author

Yeoh, WK, Cui, XY, Gault, B, De Silva, KSB, Xu, X, Liu, HW, Yen, HW, Wong, D, Bao, P, Larson, DJ, Martin, I, Li, WX, Zheng, RK, Wang, XL, Dou, SX, Ringer, SP, Yeoh, WK, Cui, XY, Gault, B, De Silva, KSB, Xu, X, Liu, HW, Yen, HW, Wong, D, Bao, P, Larson, DJ, Martin, I, Li, WX, Zheng, RK, Wang, XL, Dou, SX, and Ringer, SP

Abstract

Due to their graphene-like properties after oxygen reduction, incorporation of graphene oxide (GO) sheets into correlated-electron materials offers a new pathway for tailoring their properties. Fabricating GO nanocomposites with polycrystalline MgB2 superconductors leads to an order of magnitude enhancement of the supercurrent at 5 K/8 T and 20 K/4 T. Herein, we introduce a novel experimental approach to overcome the formidable challenge of performing quantitative microscopy and microanalysis of such composites, so as to unveil how GO doping influences the structure and hence the material properties. Atom probe microscopy and electron microscopy were used to directly image the GO within the MgB2, and we combined these data with computational simulations to derive the property-enhancing mechanisms. Our results reveal synergetic effects of GO, namely, via localized atomic (carbon and oxygen) doping as well as texturing of the crystals, which provide both inter- and intra-granular flux pinning. This study opens up new insights into how low-dimensional nanostructures can be integrated into composites to modify the overall properties, using a methodology amenable to a wide range of applications. © 2014 the Partner Organisations.

Published

2014

10. On the roles of graphene oxide doping for enhanced supercurrent in MgB 2 based superconductors

Author

Yeoh, WK, Cui, XY, Gault, B, De Silva, KSB, Xu, X, Liu, HW, Yen, HW, Wong, D, Bao, P, Larson, DJ, Martin, I, Li, WX, Zheng, RK, Wang, XL, Dou, SX, Ringer, SP, Yeoh, WK, Cui, XY, Gault, B, De Silva, KSB, Xu, X, Liu, HW, Yen, HW, Wong, D, Bao, P, Larson, DJ, Martin, I, Li, WX, Zheng, RK, Wang, XL, Dou, SX, and Ringer, SP

Abstract

Due to their graphene-like properties after oxygen reduction, incorporation of graphene oxide (GO) sheets into correlated-electron materials offers a new pathway for tailoring their properties. Fabricating GO nanocomposites with polycrystalline MgB2 superconductors leads to an order of magnitude enhancement of the supercurrent at 5 K/8 T and 20 K/4 T. Herein, we introduce a novel experimental approach to overcome the formidable challenge of performing quantitative microscopy and microanalysis of such composites, so as to unveil how GO doping influences the structure and hence the material properties. Atom probe microscopy and electron microscopy were used to directly image the GO within the MgB2, and we combined these data with computational simulations to derive the property-enhancing mechanisms. Our results reveal synergetic effects of GO, namely, via localized atomic (carbon and oxygen) doping as well as texturing of the crystals, which provide both inter- and intra-granular flux pinning. This study opens up new insights into how low-dimensional nanostructures can be integrated into composites to modify the overall properties, using a methodology amenable to a wide range of applications. © 2014 the Partner Organisations.

Published

2014

11. On the roles of graphene oxide doping for enhanced supercurrent in MgB 2 based superconductors

Author

Yeoh, W K, Cui, X Y, Gault, B, De Silva, K S. B, Xu, X, Liu, H W, Yen, H. -W, Wong, D, Bao, P, Larson, D J, Martin, I, Li, W X, Zheng, R K, Wang, X L, Dou, S X, Ringer, S P, Yeoh, W K, Cui, X Y, Gault, B, De Silva, K S. B, Xu, X, Liu, H W, Yen, H. -W, Wong, D, Bao, P, Larson, D J, Martin, I, Li, W X, Zheng, R K, Wang, X L, Dou, S X, and Ringer, S P

Abstract

Due to their graphene-like properties after oxygen reduction, incorporation of graphene oxide (GO) sheets into correlated-electron materials offers a new pathway for tailoring their properties. Fabricating GO nanocomposites with polycrystalline MgB2 superconductors leads to an order of magnitude enhancement of the supercurrent at 5 K/8 T and 20 K/4 T. Herein, we introduce a novel experimental approach to overcome the formidable challenge of performing quantitative microscopy and microanalysis of such composites, so as to unveil how GO doping influences the structure and hence the material properties. Atom probe microscopy and electron microscopy were used to directly image the GO within the MgB2, and we combined these data with computational simulations to derive the property-enhancing mechanisms. Our results reveal synergetic effects of GO, namely, via localized atomic (carbon and oxygen) doping as well as texturing of the crystals, which provide both inter- and intra-granular flux pinning. This study opens up new insights into how low-dimensional nanostructures can be integrated into composites to modify the overall properties, using a methodology amenable to a wide range of applications.

Published

2014

12. On the roles of graphene oxide doping for enhanced supercurrent in MgB 2 based superconductors

Author

Yeoh, W K, Cui, X Y, Gault, B, De Silva, K S. B, Xu, X, Liu, H W, Yen, H. -W, Wong, D, Bao, P, Larson, D J, Martin, I, Li, W X, Zheng, R K, Wang, X L, Dou, S X, Ringer, S P, Yeoh, W K, Cui, X Y, Gault, B, De Silva, K S. B, Xu, X, Liu, H W, Yen, H. -W, Wong, D, Bao, P, Larson, D J, Martin, I, Li, W X, Zheng, R K, Wang, X L, Dou, S X, and Ringer, S P

Abstract

Due to their graphene-like properties after oxygen reduction, incorporation of graphene oxide (GO) sheets into correlated-electron materials offers a new pathway for tailoring their properties. Fabricating GO nanocomposites with polycrystalline MgB2 superconductors leads to an order of magnitude enhancement of the supercurrent at 5 K/8 T and 20 K/4 T. Herein, we introduce a novel experimental approach to overcome the formidable challenge of performing quantitative microscopy and microanalysis of such composites, so as to unveil how GO doping influences the structure and hence the material properties. Atom probe microscopy and electron microscopy were used to directly image the GO within the MgB2, and we combined these data with computational simulations to derive the property-enhancing mechanisms. Our results reveal synergetic effects of GO, namely, via localized atomic (carbon and oxygen) doping as well as texturing of the crystals, which provide both inter- and intra-granular flux pinning. This study opens up new insights into how low-dimensional nanostructures can be integrated into composites to modify the overall properties, using a methodology amenable to a wide range of applications.

Published

2014

13. Atom probe microscopy characterization of as quenched Zr-0.8 wt% Fe and Zr-0.15 wt% Cr binary alloys

Author

Gault, B., Felfer, P. J., Ivermark, M., Bergqvist, Hans, Cairney, J. M., Ringer, S. P., Gault, B., Felfer, P. J., Ivermark, M., Bergqvist, Hans, Cairney, J. M., and Ringer, S. P.

Abstract

Two binary Zr-alloys with a β-quenched structure were analysed by atom probe tomography to provide a better understanding of how Fe and Cr perform in industrial Zr alloys. In a Zr-0.8 Fe (wt%) alloy, we observed a dispersion of precipitates with a composition close to Zr3Fe, and Fe segregated to a grain boundary. In a Zr-0.15 Cr (wt%) alloy, Cr was observed in solid solution in the Zr-matrix and segregated to grain boundary where it formed small spherical particles or elongated atmospheres., QC 20130213

Published

2013

14. Quantitative dopant distributions in GaAs nanowires using atom probe tomography

Author

Du, S., Burgess, Timothy, Gault, B., Gao, Qiang, Bao, Peite, Li, Li, Cui, Xiangyuan, Yeoh, Wai Kong, Liu, Hong-Wei, Yao, Lan, Ceguerra, A.V., Jagadish, Chennupati, Ringer, Simon P., Zheng, Rongkun, Tan, Hark Hoe, Du, S., Burgess, Timothy, Gault, B., Gao, Qiang, Bao, Peite, Li, Li, Cui, Xiangyuan, Yeoh, Wai Kong, Liu, Hong-Wei, Yao, Lan, Ceguerra, A.V., Jagadish, Chennupati, Ringer, Simon P., Zheng, Rongkun, and Tan, Hark Hoe

Abstract

Controllable doping of semiconductor nanowires is critical to realize their proposed applications, however precise and reliable characterization of dopant distributions remains challenging. In this article, we demonstrate an atomic-resolution three-dimens

Published

2013

15. Full tip imaging in atom probe tomography

Author

Du, S., Burgess, Timothy, Loi, Shyeh Tjing, Gault, B., Gao, Qiang, Bao, Peite, Li, Li, Cui, Xiangyuan, Yeoh, Wai Kong, Jagadish, Chennupati, Ringer, Simon Peter, Zheng, Rongkun, Tan, Hark Hoe, Du, S., Burgess, Timothy, Loi, Shyeh Tjing, Gault, B., Gao, Qiang, Bao, Peite, Li, Li, Cui, Xiangyuan, Yeoh, Wai Kong, Jagadish, Chennupati, Ringer, Simon Peter, Zheng, Rongkun, and Tan, Hark Hoe

Abstract

Atom probe tomography (APT) is capable of simultaneously revealing the chemical identities and three dimensional positions of individual atoms within a needle-shaped specimen, but suffers from a limited field-of-view (FOV), i.e., only the core of the specimen is effectively detected. Therefore, the capacity to analyze the full tip is crucial and much desired in cases that the shell of the specimen is also the region of interest. In this paper, we demonstrate that, in the analysis of III-V nanowires epitaxially grown from a substrate, the presence of the flat substrate positioned only micrometers away from the analyzed tip apex alters the field distribution and ion trajectories, which provides extra image compression that allows for the analysis of the entire specimen. An array of experimental results, including field desorption maps, elemental distributions, and crystallographic features clearly demonstrate the fact that the whole tip has been imaged, which is confirmed by electrostatic simulations.

Published

2013

16. Quantification of the zinc dopant concentration in GaAs nanowires

Author

Burgess, Timothy, Du, S., Gault, B., Gao, Qiang, Zheng, Rongkun, Jagadish, Chennupati, Tan, Hark Hoe, Burgess, Timothy, Du, S., Gault, B., Gao, Qiang, Zheng, Rongkun, Jagadish, Chennupati, and Tan, Hark Hoe

Abstract

The zinc dopant concentration and distribution in GaAs nanowires is quantified by atom probe tomography. Material deposited radially by a vapour-solid process is shown to have a significantly higher dopant concentration in comparison to the core which grows by the vapour-liquid-solid process. Zinc concentrations of up to 7×1019 and 5×1020 atoms/cm3 are measured for core and shell materials respectively. Dopant activation is confirmed by electrical characterization which demonstrates an orders of magnitude increase in nanowire conductivity.

Published

2012

17. A lattice-rectified and detection efficiency compensated APT reconstruction

Author

Moody, M, Ceguerra, A, Breen, A, Gault, B, Stephenson, L, Marceau, Ross, Ringer, S, Moody, M, Ceguerra, A, Breen, A, Gault, B, Stephenson, L, Marceau, Ross, and Ringer, S

Published

2011

18. Direct Observation of Local Potassium Variation and Its Correlation to Electronic Inhomogeneity in (Ba 1 - x K x )Fe 2 As 2 Pnictide

Author

Yeoh, Wai Kong, Gault, B., Cui, X. Y., Zhu, C., Moody, M.P., Li, Li (Lily), Zheng, Rongkun, Wang, Xiao Lin, Li, W.X., Dou, S X, Sun, G.L., Lin, C.T., Ringer, Simon P., Yeoh, Wai Kong, Gault, B., Cui, X. Y., Zhu, C., Moody, M.P., Li, Li (Lily), Zheng, Rongkun, Wang, Xiao Lin, Li, W.X., Dou, S X, Sun, G.L., Lin, C.T., and Ringer, Simon P.

Abstract

Local fluctuations in the distribution of dopant atoms are thought to cause the nanoscale electronic disorder or phase separation in pnictide superconductors. Atom probe tomography has enabled the first direct observations of dopant species clustering in

Published

2011

19. Atom probe tomography of reactor pressure vessel steels: An analysis of data integrity

Author

Hyde, J., Burke, M., Gault, B., Saxey, David, Styman, P., Wilford, K., Williams, T., Hyde, J., Burke, M., Gault, B., Saxey, David, Styman, P., Wilford, K., and Williams, T.

Abstract

In this work, the importance of optimising experimental conditions for the analysis of reactor pressure vessel (RPV) steels using atom probe tomography is explored. The quality of the resultant atom probe data is assessed in terms of detection efficiency, noise levels and mass resolution. It is demonstrated that artefacts can exist even when experimental conditions have been optimised. In particular, it is shown that surface diffusion of some minority species, including P and Si, to major poles prior to field evaporation can be an issue. The effects were most noticeable during laser pulsing. The impact of surface migration on the characterisation of dislocations and grain boundaries is assessed. The importance of selecting appropriate regions of the reconstructed data for subsequent re-analysis is emphasised.

Published

2011

20. Some aspects of the field evaporation behaviour of GaSb

Author

Müller, M., Saxey, David, Smith, G., Gault, B., Müller, M., Saxey, David, Smith, G., and Gault, B.

Abstract

In-depth analysis of pulsed laser atom probe tomography (APT) data on the field evaporation of the III–V semiconductor material GaSb reveals strong variations in charge states, relative abundances of different cluster ions, multiplicity of detector events and spatial correlation of evaporation events, as a function of the effective electric field at the specimen surface. These variations are discussed in comparison with the behaviour of two different metallic specimen materials, an Al-6XXX series alloy and pure W, studied under closely related experimental conditions in the same atom probe instrument. It is proposed that the complex behaviour of GaSb originates from a combination of spatially correlated evaporation events and the subsequent field induced dissociation of cluster ions, the latter contributing to inaccuracies in the overall atom probe composition determination for this material.

Published

2011

21. High-resolution nanostructural investigation of Zn4Sb 3 alloys

Author

Gault, B., Marquis, E., Saxey, David, Hughes, G., Mangelinck, D., Toberer, E., Snyder, G., Gault, B., Marquis, E., Saxey, David, Hughes, G., Mangelinck, D., Toberer, E., and Snyder, G.

Abstract

Zinc antimonides exhibit high thermoelectric figures of merit and bear great potential for power generation. To advance the understanding of the structure-property relationship in these alloys, the microstructure of a nanocrystalline Zn4Sb3 alloy, containing 57.29 at.% Zn, was investigated by scanning electron microscopy and atom probe tomography. Chemical inhomogeneities were observed at grain boundaries. Within the grains the distribution of Zn shows large fluctuations inducing a complex microstructure made of Zn-rich and Sb-rich regions at a nanometer scale. © 2010 Acta Materialia Inc. Published by Elsevier Ltd. All rights reserved.

Published

2010

22. Investigation of self-assembled monolayer by atom probe microscopy

Author

Gault, B, Yang, Wenrong, Ratinac, KR, Zheng, R, Braet, F, Ringer, SP, Gault, B, Yang, Wenrong, Ratinac, KR, Zheng, R, Braet, F, and Ringer, SP

Abstract

Extended abstract of a paper presented at Microscopy and Microanalysis 2009 in Richmond, Virginia, USA, July 26 – July 30, 2009

Published

2009