Introduction
With advancements in aberration-corrected electron optics, the resolution in scanning transmission electron microscopy (STEM) has been significantly improved [Reference Muller, Fitting, Murfitt, Song, Hwang, Silcox, Dellby and Krivanek1]. More importantly, the reduction of the probe size and the increase of the probe current density enable the acquisition of elemental maps at the atomic scale in a fast manner using both EELS and EDS. With the latest generations of EELS spectrometers [Reference Gubbens, Barfels, Trevor, Twesten, Thomas, Menon, Kraus, Mao and McGinn2], atomic resolution compositional and chemical maps allow interfaces [Reference Monkman, Adamo, Mundy, Shai, Harter, Shen, Brganov, Muller, Schlom and Shen3], oxidation state, and even single atoms [Reference Tan, Turner, Yucelen, Verbeeck and Van4, Reference Suenaga and Koshino5] to be examined with increasing detail. These improvements have also enabled elemental and chemical maps to be acquired rapidly using both low- and high-energy edges from elements across the periodic table, including heavy atoms such Au or Pt [Reference Longo and Twesten6, Reference Longo, Twesten and Thomas7, Reference Longo8, Reference Longo9]. On the EDS side, the introduction of large-area silicon drift detectors (SDD) [Reference Schlossmacher, Klenov, Freitag and Von10, Reference Allen, D'Alfonso, Freitag and Klenov11] has allowed these high-beam-current sources to be fully utilized. Improved detector area and support for higher count rates, compared to the previous generation of EDS detectors, allows the acquisition of EDS intensity maps from most types of material in the STEM, even for moderately thin samples. For the case of light elements, the reduced detector dead layer of SDD-based systems partially overcomes the very low florescence yield typical of low-energy X-ray lines. Also as reported in [Reference Allen, D'Alfonso, Freitag and Klenov11], atomic-level X-ray maps using fast detectors and bright sources can now be collected under some conditions. Because EDS and EELS provide complementary information about the sample, and are both generated with the electron beam, it would be wasteful to not acquire both datasets with every sample run.
Simultaneous EELS/EDS acquisition systems have been available since the late 1990s, but those systems are unable to keep up with the data rates of modern spectrometers. Recent advances in acquisition strategies and hardware have overcome the two main challenges of joint EELS/EDS data acquisition: (1) the exact pixel-to-pixel synchronization among different pieces of hardware, such as analog STEM detectors, serial counting EDS detectors, and parallel imaging EELS detectors, and (2) the vast amount of information that is generated by the system, from tens of kbits/s for the EDS pulses to the many MBytes/s of data from the EELS detector. As described in [Reference Longo and Twesten6], these challenges have been overcome by acquiring the data in a hardware-synchronized mode. The individual acquisition systems collect their data independent of the other but are linked together by a timing signal. The synchronization signal is delivered by the EELS spectrometer by means of timing pulse at the end of each acquired EELS spectrum. This pulse is used to advance the beam position and inform the EDS system that the pixel has advanced, resulting in a highly efficient detection system with very little pixel-to-pixel dead time. Following initial successful results of simultaneous high-speed EELS and EDS analysis from a catalyst sample containing PdAu nanoparticles [Reference Longo and Twesten6], in this article we use this acquisition method to create the first reported high-speed jointly acquired EELS and EDS spectrum images at atomic resolution.
Methods and Materials
Instrumentation. Data was acquired at TU-Graz in Austria using a probe-corrected FEI Titan G2 STEM equipped with a X-FEG high-brightness electron source operating at 200 kV. The instrument is also equipped with a four-quadrant SDD detector (FEI Super-X) [Reference Schlossmacher, Klenov, Freitag and Von10], controlled by the Bruker Esprit system and a GIF Quantum ERS imaging filter for EELS acquisition [Reference Gubbens, Barfels, Trevor, Twesten, Thomas, Menon, Kraus, Mao and McGinn2]. The EELS spectrometer is configured with the following features: (a) DualEELS™ capability, which allows two different regions of the EELS spectrum to be recorded nearly simultaneously (Δt = 10 μs) [Reference Gubbens, Barfels, Trevor, Twesten, Thomas, Menon, Kraus, Mao and McGinn2, Reference Scott, Thomas, Mackenzie, McFadzean, Craven and Nicholson12]; (b) a low dispersion mode, which allows EELS data to be recorded with an energy range up to 2000 eV (or 4000 eV in DualEELS mode); (c) a fast 2-k CCD, which allows EELS acquisition at over 1000 spectra per second [Reference Gubbens, Barfels, Trevor, Twesten, Thomas, Menon, Kraus, Mao and McGinn2]; and (d) a dodecapole lens system capable of correcting spectral aberrations up to the 5th order, allowing collections angles well over 100 mrad to be used while maintaining sub-eV energy resolution [Reference Gubbens, Barfels, Trevor, Twesten, Thomas, Menon, Kraus, Mao and McGinn2].
Test specimen. The sample analyzed was a SrTiO3 (100) crystal. A relatively thick sample for this type of measurement (> 0.7 t/λ as measured by low-loss EELS) was used to generate sufficient EDS counts for the analysis. This results in some loss of spatial resolution.
Acquisition parameters. Data were acquired using a STEM probe of 160 pA measured on the microscope fluorescence screen. This STEM microscope is capable of much higher current, but a relatively low current was used in order to reduce the beam damage. The probe convergence angle was 22 mrad, and the EELS collection angle was estimated to be just over 40 mrad. The EDS collection angle is reported to be ~0.7 sr but was not independently measured in these experiments. Three different signals (ADF, EDS, and EELS core-loss) were recorded simultaneously. The region of the EELS spectrum from 300 eV to 2300 eV was acquired using a dwell time per pixel of 10 ms. The EDS spectrum was acquired simultaneously, integrating counts over the entire pixel dwell time employed for the EELS acquisition. The entire 70 × 57 pixel spectrum imaging dataset was taken in just 48 seconds. This is the time from the start to the moment when all the EDS and EELS spectra were transferred from the hardware buffers to the Gatan computer. The actual acquisition time was somewhat shorter (~40 seconds) but was not directly measured. It is important to mention that no drift correction was employed during the acquisition of the spectrum imaging (SI). Because the sample was inserted into the microscope less than 1 hour before the data were collected, some residual spatial drift was observed in the elemental maps.
Results
Figure 1 shows the ADF image used as a survey image for the acquisition of the EELS and EDS SI. EELS and EDS elemental maps were taken from the area highlighted in the green box. Figures 2b and 2c show EELS and EDS spectra from a single pixel extracted from the region in the red box shown in the EELS SI in Figure 2a. The EELS spectrum shows a reasonable amount of signal. The Sr L2,3-edges at 1940 eV stand out quite well above the background, and the entire EELS spectrum contains approximately 665k electrons. Unlike EELS, the EDS spectrum shows a limited number of counts, and the Sr L and Ti K lines are barely detectable. There are approximately 117 X-ray counts in the entire spectrum that extends up to 20 keV. The stronger signal in the EELS spectrum results in reasonable signal-to-noise ratio (SNR) at the individual spectrum level even with this short exposure time (10 ms/pixel). The small number of counts in the EDS spectrum precludes any quantification at the single-spectrum level. EELS elemental maps of Sr L2,3-edges at 1940 eV, Ti L2,3-edges at 456 eV, and O K-edge at 532 eV were extracted using MLLS fitting [Reference Thomas13, Reference Riegler and Kothleitner14] as previously described in [Reference Longo, Twesten and Thomas7]. In the case of EDS, elemental maps were extracted using the Sr La lines at 1.81 keV and the Ti Ka at 4.51 keV using an empirical Kramers background [Reference Lifshin15] fitting followed by multiple linear least square (MLLS) fitting of each peak family represented by a set of Gaussian peaks. X-ray maps using the O K line were attempted, but because of the limited signal and also the overlap of the O K and Ti L peaks, the results were unsatisfactory.
Figures 3a and 3b show the Ti elemental maps obtained using EELS and EDS, respectively. Qualitatively, there is less noise and higher contrast in the EELS map compared to that from EDS. Figures 4a and 4b show the Sr elemental maps obtained using EELS and EDS, respectively. In both cases the Sr L transition was used. As in the case of the Ti elemental maps, the EELS map shows less noise and seems sharper than that obtained using EDS. To measure the relative quality of each map, the signal intensity was analyzed from a uniform region across each single elemental map. This 5 × 5 pixel region is indicated by the red boxes in Figures 3 and 4. The extracted data from the 5 × 5 pixel region are summarized in Table 1. In the case of the Ti elemental maps, the SNR for the EELS data was ~30, almost 7 times greater than the EDS data. In the case of the Sr elemental maps, the SNR was ~11 and ~5 for EELS and EDS, respectively, giving over 2× improvement for the EELS data. The SNR in the EDS data is limited by Poisson statistics, and the collection efficiency would need to be more greatly improved (2 times for the Sr and over 6 times for the Ti) even for the relatively thick samples used here. Figures 5a and 5b show the O K elemental maps using EELS and EDS, respectively. The EELS data does not completely resolve individual O atoms, but it does show the distributed oxygen framework. As mentioned above, the EDS data show no oxygen structure.
Figures 6a and 6b show colorized elemental maps of Ti and Sr obtained using EDS and EELS, respectively. The left half of each color map shows the raw experimental data, whereas the right half shows the data after smoothing out of some of the noise. Qualitatively, the EELS maps appear to be sharper and show stronger contrast. The distinction between EELS and EDS elemental maps is more clearly seen in the raw data, emphasizing the superiority of EELS at the single-spectrum limit and the misleading effects of strong spatial averaging as a result of the smoothing procedure employed to de-noise the data.
Discussion
The EELS and EDS data presented here can be regarded as highly complementary. The main difference is that for the EDS case, each individual pixel carries little information because of the low SNR of the data. However, the high peak-to-background ratio of the EDS technique allows summation of adjacent data, almost indefinitely improving the detection limits at the expense of spatial resolution. The EELS data, on the other hand, has very high collection efficiency resulting in high SNRs in each individual spectrum. Summing adjacent pixels improves the detection limits considerably but will show diminishing returns once the shot noise in the signal integral becomes irrelevant. The techniques further complement each other when identifying artifacts in the data. For example, secondary fluorescence and preferential absorption in the EDS data can be determined from comparison with the EELS data, and possible missing elements in the EELS data range acquired can be identified in the summed EDS signal. Furthermore, the ability of combining composition measurements from EELS and EDS with physical and electronic information also available only from EELS (for example, plasmonic, bandgap, and density of states information) [Reference Egerton16] promises to open whole new avenues of materials analysis.
Conclusions
A system for fast and efficient acquisition of both EELS and EDS spectra allows the routine collection of both of these complementary data signals. There is no longer a need to choose between analytical techniques; both EELS and EDS can be acquired easily with every data run. The data presented here show the complementary nature of having both high signal-to-noise and high peak-to-background data acquired at the same location at the same time.
Acknowledgments
We would like to thank Dr. Yan Xin of Florida State University for kindly providing the TEM specimen used for the experiment, Professor Gerald Kothleitner of TU-Graz for many discussions and access to the TEM facilities, and Mr. Arno Meingast for expert assistance configuring the microscope for this experiment.