Atom Probe Field Ion Microscopy Research Articles

Acquisition of field ion microscope image using deflector during atom probe analysis

Atom probe (AP) is an elemental analysis technique that ionizes surface atoms by a strong field formed by a sharp needle-shaped sample and identifies ions in an atom-by-atom manner by the time of flight mass spectrometer. The detection efficiency of AP has been estimated to be extremely high by the correlation to field ion microscopy (FIM) observations, which show the surface morphology change in atomic scale during the field evaporation of the surface layer. The estimation of detection efficiency has been indirectly done by the comparison of AP data and FIM observation. We evaluated the detection efficiency of AP directly from ion data and counting spot change in FIM images by repeating two measurements sequentially in this work. The experimentally obtained ratio between the detected count over disappeared spots was 10/33 ≈ 0.30, which was ca. 1/2 of the optimal value expected from the opening area ratio of the microchannel plate (∼0.60).

MSA Focused Interest Groups: Atom Probe Field Ion Microscopy and Focused Ion Beam Microscopy

MSA Focused Interest Groups: Atom Probe Field Ion Microscopy and Focused Ion Beam Microscopy

Combining complementary techniques to study precipitates in steels

AbstractUnderstanding the precipitation reactions is of vital importance for the development of advanced steels. A comprehensive characterization of all phases, however, is still demanding in these complex materials. Transmission electron microscopy is widely used, but the prevailing ferromagnetism makes the analysis of small precipitates difficult. Furthermore, the investigated specimen volume is small, making statistically relevant findings time-consuming. Therefore, in our study, transmission electron microscopy measurements are complemented by small-angle neutron scattering and atom-probe field ion microscopy. These methods were used to characterize the precipitates in a model steel which hardens by secondary hardening carbides and an intermetallic NiAl-based phase. Assets and drawbacks of each method are discussed and it will be shown that an appropriate combination of the differently obtained findings leads to a detailed description of the precipitation behavior.

Mechanical properties of NiAl–Cr alloys in relation to microstructure and atomic defects

AbstractThe quasi-binary eutectic NiAl–Cr of the ternary Ni–Al–Cr system is composed of B2 type NiAl(Cr) solid solutions and the b.c.c. transition metal chromium as second phase. This constitution enables a systematic alloy design in dependence on the Cr content for improving elastic stiffness, high temperature strength, creep resistance, and fracture toughness of intermetallic NiAl. Elasticity and mechanical properties of NiAl(Cr) reinforced by nano-sized Cr particles or quasi-continuous Cr fibres of several microns in diameter are presented and discussed in respect to single phase NiAl and literature data. The microstructural characterization and discussion of mechanical properties of NiAl–Cr alloys are supplemented by atom probe field ion microscopy analysis (APFIM). APFIM was used to determine the atomic defect structures, the Cr site preference and reveals Cr segregations at antiphase boundaries.

Review on Steel Enhancement for Nuclear RPVs

The reactor pressure vessel (RPV) is one of the most important elements of a nuclear power plant (NPP). The RPV determines the plant operational lifetime since it is not replaceable economically. The purpose of the RPV steel study and enhancement to increase the NPP’s (Nuclear Power Plants) operation lifetime from the original 30–40 years up to 60–80 years or even beyond. The RPV lifetime limited by ageing of the RPV steels. RPV ageing highly depends on the main environmental effects: fast neutron radiation, thermal effects causing thermal ageing and low-cycle fatigue. Firstly, the chemical composition via aged mechanical properties was studied. Efforts to increase the toughness against the radiation embrittlement was enhanced by the appearance of the modern microstructural testing devices such as APFIM (atom probe field ion microscopy), SANS (small-angle neutron scattering) positron annihilation spectroscopy (PAS), transmission electron microscopy (TEM) and Mössbauer spectroscopy (MS). The information on the effect of alloying and polluting elements for the microstructure allowed us to produce increased ageing toughness of the RPVs, and to enhance the safety and lifetime calculations of them, supporting long-term safe operation (LTO).

Chemical segregation and precipitation at anti-phase boundaries in thermoelectric Heusler-Fe2VAl

Fe2VAl exhibits promising properties for thermoelectric applications. Here, we investigated the microstructure of melt spun Fe2VAl using electron microscopy, atom probe tomography and field ion microscopy. We observe platelet-shaped VCxNy precipitates in the vicinity of antiphase boundaries (APB) oriented along the {100}-plane. The mean distance between these precipitates is (140 ± 40) nm. This distance is shorter than the mean free phonon path at room temperature in Fe2VAl. Thus, these VCxNy precipitates, combined with the APB may efficiently lower the thermal conductivity of the alloy.

Measuring grain boundary segregation: tomographic atom probe field ion microscopy (APFIM) vs. analytical scanning transmission electron microscopy (STEM)

Grain boundary segregation is an important phenomenon in metallurgy and semiconductor technology. Some recent studies by tomographic atom probe field ion microscopy (APFIM) claim to have measured the interfacial excess of atoms segregated to grain boundaries with ultra-high precision, down to 0.01-0.02 atoms/nm2. This study critically evaluates these claims by simulations. It is shown that atom probe tomography is no ‘magic bullet’ and suffers similar physical constraints as analytical scanning transmission electron microscopy (STEM). Data analyses from both methods have much in common in terms of geometry, performance, systematic and statistical errors. It is shown that an analysis method previously developed for (S)TEM called conceptEM can also successfully be applied to APFIM data.

My Life With Erwin: The Beginning of an Atom-Probe Legacy.

The atom-probe field ion microscope was introduced in 1967 at the 14th Field Emission Symposium held at the National Bureau of Standards (now, NIST) in Gaithersburg, Maryland. The atom-probe field ion microscope was, and remains, the only instrument capable of determining "the nature of one single atom seen on a metal surface and selected from neighboring atoms at the discretion of the observer". The development of the atom-probe is a story of an instrument that one National Science Foundation (NSF) reviewer called "impossible because single atoms could not be detected". It is also a story of my life with Erwin Wilhelm Müller as his graduate student in the Field Emission Laboratory at the Pennsylvania State University in the late 1960s and his strong and volatile personality, perhaps fostered by his pedigree as Gustav Hertz's student in the Berlin of the 1930s. It is the story that has defined by scientific career.

On the Physics of Anomalies of Boron Nanosegregation at Dislocations in FeAl

We present results of the constructive critical analysis and interpretation of some recent studies (Blavette, Sauvage, Wilde and others) at the atomic scale (using three-dimensional atom-probe field-ion microscopy) of impurity nanosegregation at dislocations, including “Cottrell atmospheres”, and grain boundaries in deformed intermetallics and metallic materials, and their relevance to mechanical properties and diffusion processes.

Microstructure of NbTi superconducting alloy

A superconducting multifilament wire made of Nb-60 at.% Ti alloy was investigated by methods of atom probe/field ion microscopy (APFIM), three-dimensional atom probe (3DAP), high resolution electron microscopy (HREM) and computer simulation. The results of the APFIM and HREM analysis suggest, that the specimens contain two phases, a bcc structure (β-phase), and a hcp structure (α-phase). The mesascopic and nanoscale heterogeneities of element concentration in *-phase were observed. Atom probe analyses of annealed NbTi superconductors and a statistical processing of the chains of atoms, consistently registered by mass-analyses, indicated that no atomic clusters were formed in alloy prior to the onset of the second phase formation. The β-phase and niobium enriched phase have the configurations extended along the wire axis, the nanoscale heterogeneity inside the β-phases was nearly isotropic. An atomic structure of interphase boundaries has been determined using HREM and atomistic structure calculations. Interphase boundaries in Nb-Ti alloy are coherent or semi-coherent in spite of the existence of the irregular microprotrusions.The boundaries between α- and β-phases reveal the absence of the rigid-body translation and continuity of lattice planes across the interface. It was demonstrated that the method of simulation in reciprocal space is computationally efficient for investigations of the atomic structure and energy of coherent and non-coherent interphase boundaries. The extremely high critical current density in the optimized Nb-Ti can be due to the coherent structure of interphase boundaries.

Field-ion microscopy of the boundary region of metal interfaces

The atomic structure of boundary regions at interfaces in metal samples subjected to intense external action has been studied by field-ion microscopy (FIM). An analysis of data obtained by FIM, atom-probe FIM, and atom-probe tomography on the atomic structure of planar defects in the samples with metal interfaces upon irradiation and the action of other factors shows that their boundary regions have different widths within 0.8–1.5 nm, depending on the type and intensity of external action. Experimental data on the elemental composition of phase interfaces in mechanically alloyed compounds (Cu80Co20) and doped alloys (Cu3Au + 4 at % Pt) are presented.

Gert Ehrlich

Gert Ehrlich, who made important contributions to surface science, especially in the area of atomic interactions on solid surfaces, died of leukemia on 10 August 2012 in Urbana, Illinois. Up to five weeks before his death, he worked tirelessly as a professor in the materials science department at the University of Illinois at Urbana-Champaign. He coauthored more than 200 scientific articles and the book Surface Diffusion: Metals, Metal Atoms, and Clusters (Cambridge University Press, 2010).Gert was born on 22 June 1926 in Vienna. After Germany annexed Austria in 1938, Gert and his father, who was Jewish (his mother was Catholic), were detained for questioning but, luckily, released. His father immediately departed for the US, and in May 1939 Gert and his sister, Dorothy, arrived unescorted in New York on the T.S.S. Veendam and were reunited with their father. What might have been a harrowing voyage had become a grand adventure: Gert had investigated all aspects of the ship’s operation and explored the ship from top to bottom. His mother joined the family several months later.In 1944 Gert enrolled at Columbia University. He served in the US Army from 1945 to 1947 and then returned to graduate from the university with honors in chemistry in 1948. He obtained his PhD in chemistry from Harvard University in 1952 under adviser Paul Doty; his thesis title was “Studies on synthetic polyampholytes.” Gert remained at Harvard for a year as a National Institutes of Health fellow. He then served a year as a research associate in the University of Michigan physics department, where he worked with Gordon Sutherland on IR spectroscopy of macromolecules.In 1953 Gert accepted a full-time appointment at the General Electric Research Laboratory in Schenectady, New York, where he studied the kinetics of gas–solid interactions. He developed temperature-programmed, or flash, desorption techniques for quantitative kinetic studies at the gas–solid interface and demonstrated the importance of distinct binding sites in chemisorption phenomena.The field ion microscope, invented in 1951 by Erwin Müller, enabled Gert to probe the underlying atomic details of his macroscopic observations. Gert made unique chemisorption studies on single-crystal surfaces and the first quantitative observations of individual atoms diffusing on a metal surface. His resulting 1966 article with Frank Hudda in the Journal of Chemical Physics has been cited more than 1000 times.Gert accepted a professorship at the University of Illinois in 1968. Leading a small group of graduate students and postdocs, he expanded his research toward surface studies on an atomic scale. Using an atom-probe field ion microscope, Gert and his group made the first direct observation of an adatom exchange mechanism. They observed and characterized numerous aspects of surface diffusion, including interior step-edge barriers, reflective plane-edge barriers, adatom–vacancy interactions, temperature-dependent long jumps, and adatom cluster motion. Gert and his group used a variety of theoretical and experimental methods to study atomic behavior and transformed the apparently hopelessly complicated subject of surface diffusion at the atomic scale into one much more understandable and explainable.Among the several honors Gert received were the 1979 Medard W. Welch Award from the American Vacuum Society and the 1982 American Chemical Society Award in Colloid and Surface Chemistry. Through a 1992 research award from the German Alexander von Humboldt Foundation, he worked on boundary layer chemistry and interfacial chemistry at the Fritz Haber Institute in Berlin with Gerhard Ertl and Jochen Block.Gert was an extremely careful and extraordinarily attentive researcher, with the highest achievable vacuum and precise timing and temperature controls. Gert also was merciless in the proper statistical analysis of data—no small task in the early slide-rule days when access to a computer meant a time-sharing connection on a teletype at 10 characters per second.Perhaps Gert’s most endearing characteristic was his concern for students. His door was always open. When a student would stop by with a question, Gert usually answered with another question to challenge the student. He established a mentoring system in which current students taught the necessary know-how and unpublished techniques to incoming students. When not in the lab, he could easily be found: As he wandered the halls, he would produce a low, enigmatic, warbling whistle, usually his unique rendering of a classical opera aria.Gert was a curious scientist, and his precise work on the behavior of atoms on surfaces was foundational to modern nanoscience and technology. He also was an excellent teacher who compulsively prepared every lecture, even on material he had previously taught. On receiving news about the success of a former student, he would sport a generous grin and his eyes would sparkle.Gert EhrlichPPT|High resolution© 2013 American Institute of Physics.

Influence of state of Nb on recrystallization temperature during annealing in cold-rolled low-carbon steels

The influence of state of Nb on recrystallization temperature during annealing in cold-rolled low-carbon steels was investigated. Two kinds of specimens showing a remarkable difference in recrystallization temperature were prepared. Differences in the features of Nb-containing precipitates larger than 3nm were rarely observed, whereas differences in precipitates smaller than 3nm were confirmed by atom-probe field-ion microscopy in each hot-rolled sheet. The difference in the recrystallization temperatures of both specimens probably originates in the state of Nb at the atomic scale before annealing.

Atom probe analysis of the bulk amorphous Nd58Fe30Al10Dy2 ferromagnet

The microstructure and composition distributions of the bulk amorphous Nd58Fe30Al10Dy2 alloy in the as-cast state have been studied using the atom probe field ion microscopy. The microstructure of the as-cast alloy comprised two phases: nanocrystalline particles and amorphous matrix phase. The exact compositions of the nanocrystalline particles and amorphous matrix have been determined for the first time. The added Dy atoms partitioned into the amorphous matrix phase. These quantitative results provide scientific basis for resolving the coercivity mechanism problems in the bulk amorphous alloys.

Multiscale characterisation of weldments

In this review, a brief introduction to different multiscale characterisation techniques and their application to the characterisation of weldments is presented. The techniques are presented from a historical point of view. The techniques reviewed include optical microscopy, electron microscopy, atom probe field ion microscopy, microhardness mapping and nanoindentation. Although these techniques are discussed with examples from fusion welds, they can easily be applied to solid state welding processes. The paper also refers to other advanced characterisation techniques that are discussed in detail in other sections of this special issue.

Direct Observation and Quantification of Nanoscale Spinodal Decomposition in Super Duplex Stainless Steel Weld Metals

Three variants of super duplex stainless steel weld metals with the basic composition 29Cr-8Ni-2Mo (wt%) were investigated. The nitrogen content of the three materials was 0.22%, 0.33% and 0.37%, respectively. Isothermal heat treatments were performed at 450 degrees C for times up to 243 h. The hardness evolution of the three materials was found to vary with the overall concentration of the nitrogen. Atom probe field ion microscopy (APFIM) was used to directly detect and quantify the degree of spinodal decomposition in different material conditions. 3-DAP atomic reconstruction clearly illustrate nanoscale variation of iron rich (alpha) and chromium rich (alpha') phases. A longer ageing time produces a coarser microstructure with larger alpha and alpha' domains. Statistical evaluation of APFIM data showed that phase separation was significant already after 1 h of ageing that gradually became more pronounced. Although nanoscale concentration variation was evident, no significant influence of overall nitrogen content on the degree of spinodal decomposition was found.

Atom probe tomography

This introductory tutorial describes the technique of atom probe tomography for materials characterization at the atomic level. The evolution of the technique from the initial atom probe field ion microscope to today's state-of-the-art three dimensional atom probe is outlined. An introduction is presented on the basic physics behind the technique, the operation of the instrument, and the reconstruction of the three-dimensional data. The common methods for analyzing the three-dimensional atom probe data, including atom maps, isoconcentration surfaces, proximity histograms, maximum separation methods, and concentration frequency distributions, are described.

Microstructural Evolution during Creep of Alloy 800HT in the Temperature Range 600 °C to 1000 °C

The microstructure of SANICRO 31HT (alloy 800HT) creep tested to a maximum of 85,388 hours in the temperature range of 600 °C to 1000 °C was investigated. Coarse Ti(C, N) precipitates were found to form in the melt and remained stable after solution annealing and aging at all temperatures investigated. M23C6 precipitating in the range of 600 °C to 700 °C was found in two different distributions: as intergranular precipitates and as small intragranular particles. The γ′ precipitation sequence was followed at 600 °C, 650 °C, and 700 °C, and the volume fraction and precipitate diameter was assessed using energy-filtered transmission electron microscopy (EFTEM). The γ′ precipitates grew and coarsened slowly at 600 °C (10 to 30 nm) but somewhat faster at 650 °C (25 to 50 nm). The volume fraction was largest at 600 °C. The γ′ precipitates formed at 700 °C were not homogeneously distributed in the matrix. Instead, γ′ was observed in the immediate vicinity of M23C6 and Ti(C, N) precipitates. Atom probe field ion microscope analysis of γ′-precipitate showed that it contained slightly more Ti than Al and that its Fe content was a few atomic percent. Nitrogen uptake was very pronounced in creep-deformed material aged at 1000 °C, and AlN formed as grain boundary needles and in the interior of grains.

Phase Transformation and Segregation to Lattice Defects in Ni-Base Superalloys

Nanostructural features of nickel-base superalloys as revealed by atom probe field ion microscopy (APFIM) and atom probe tomography (APT) are reviewed. The more salient information provided by these techniques is discussed through an almost exhaustive analysis of literature over the last 30 years. Atom probe techniques are shown to be able to measure the composition of tiny gamma' precipitates, a few nanometers in size, and to reveal chemical order within these precipitates. Phase separation kinetics in model NiCrAl alloys was investigated with both 3DAP and Monte-Carlo simulation. Results are shown to be in good agreement. Plane by plane analysis of {001} planes of Ni(3)Al-type gamma' phase makes it possible to estimate the degree of order as well as the preferential sites of various addition elements (Ti, Cr, Co, W, Ta, Re, Ru, etc.) included in superalloys. Clustering effects of Re in the gamma solid solution were also exhibited. Due to its ultrahigh depth resolution, the microchemistry of interfaces and grain boundaries can be characterized on an atomic scale. Grain boundaries in Astroloy or N18 superalloys were found to be enriched in B, Mo, and Cr and Al depleted.

Simulation of competitive Cu precipitation in steel during non-isothermal aging

A numerical model has been developed to simulate Cu precipitation in dilute bcc Fe–Cu alloys during non-isothermal aging taking into account competitive nucleation at grain boundaries, dislocations and in the matrix, and structural transformation of Cu particles that occurs during growth. The temporal evolution of number density, mean particle size and size distribution during continuous cooling is simulated and is compared with experimental observations under transmission electron microscope and three-dimensional atom probe field ion microscope. With decreasing temperature the growth and coarsening rates diminishes rapidly whereas nucleation continues to occur down to lower temperatures due to the decrease in the activation energy of nucleation and thus, distributions of fine particles can be obtained relatively easily after cooling. Precipitation and dissolution during continuous heating are simulated and are compared with experimental observations in the literature.