Quantitative material analysis using secondary electron energy spectromicroscopy

Han, Weiding; Zheng, Minrui; Banerjee, Amartya; Luo, Yong Zheng; Shen, Lei; Khursheed, Anjam

doi:10.1038/s41598-020-78973-0

Cited by 14 publications

(11 citation statements)

References 80 publications

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“…5. It is known that the use of SEM secondary electron images (SEI) combined with energy dispersion analysis (EDA) is primarily an imaging method and not a fully quantitative approach [17]. It is difficult to identify CaCO unambiguously using this approach.…”

Section: Ivc Scanning Electron Microscopy Analysismentioning

confidence: 99%

Carbon Capture Potential in Lime Modified Kaolin Clay

Iorliam¹,

Msueg²,

Anum³

2021

IJET

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This research presents the potential of combined carbon capture alongside compressive strength improvement in carbonated lime treated kaolin clay, and determines the suitability of the strength improvement for application to capping layer in road pavement. Using combined modification and carbonation treatment at controlled air voids, 4.7%-10% calcium carbonate was determined in kaolin treated with 4-8% calcium hydroxide contents in samples at 10% air voids. Strength increase was achieved in carbonated lime-treated kaolin from 170 kPa to 280 kPa compared with soaked non-carbonated lime treated kaolin, which shows significant increase of approximately 65%. This method of combined modification and carbonation in lime treated clay has the potential to capture carbon alongside improving the strength of the weak kaolin, and could be effectively used for combined carbon capture and road pavement functions.

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Section: Ivc Scanning Electron Microscopy Analysismentioning

confidence: 99%

Carbon Capture Potential in Lime Modified Kaolin Clay

Iorliam¹,

Msueg²,

Anum³

2021

IJET

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“…The signal signature for this form of contamination is greatly reduced as the FIB window is created, and as post FIB SES indicate at the time points, it is observed that this contamination does start to return to the surface of the materials as the sample undergoes conventional SEM imaging. This finding revealed that as well as the ability of SES to monitor ACC, Plasma FIB Xe exposure has the capability to remove carbon contamination from the surface of Ti without the requirement for chemical surface treatments [ 23 ]. The removal of carbon contamination is seen as an advantage for IBID fabrication, notably for nanoconductors to improve the conductivity of the deposited material and to increase the tensile elasticity of FIB fabrication microstructures [ 17 ].…”

Section: Resultsmentioning

confidence: 99%

“…The ability to monitor different forms of carbon contamination during the deposition process is still yet to be established. The most obvious reason for this is a lack of suitable characterisation tools is the combination of multiple requirements: high surface sensitivity (akin to X-ray photoelectron spectroscopy (XPS), high spatial resolution (akin to Auger electron spectroscopy) [ 21 ], and the ability to identify the carbon bonding present using low beam energies (reducing sample modification) without the need for an Ultra High Vacuum (UHV) [ 22 , 23 ]. All of these requirements may be fulfilled by Secondary Electron (SE) spectroscopy.…”

Section: Introductionmentioning

confidence: 99%

Monitoring Carbon in Electron and Ion Beam Deposition within FIB-SEM

2021

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It is well known that carbon present in scanning electron microscopes (SEM), Focused ion beam (FIB) systems and FIB-SEMs, causes imaging artefacts and influences the quality of TEM lamellae or structures fabricated in FIB-SEMs. The severity of such effects depends not only on the quantity of carbon present but also on its bonding state. Despite this, the presence of carbon and its bonding state is not regularly monitored in FIB-SEMs. Here we demonstrated that Secondary Electron Hyperspectral Imaging (SEHI) can be implemented in different FIB-SEMs (ThermoFisher Helios G4-CXe PFIB and Helios Nanolab G3 UC) and used to observe carbon built up/removal and bonding changes resulting from electron/ion beam exposure. As well as the ability to monitor, this study also showed the capability of Plasma FIB Xe exposure to remove carbon contamination from the surface of a Ti6246 alloy without the requirement of chemical surface treatments.

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“…These contrast modulations originate from the photoexcitation of local excess charge carrier distributions, which affect the configuration of surface states and the yield of SE emission. A less considered effect is that this change in charge distribution modifies the electric field outside the surface too, which in turn dynamically changes the SE collection in the SEM [1,2,4,5,6]. Both mechanisms, the changes in emission yield and in collection efficiency, contribute to the 2D dynamical SE patterns.…”

Section: Introductionmentioning

confidence: 99%

Dynamical imaging of local photovoltage at semiconductor surface by photo-assisted ultrafast scanning electron microscopy

et al. 2021

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Photo-assisted Ultrafast Scanning Electron Microscopy (USEM) maps the dynamics of surface photovoltages and local electric fields in semiconducting samples. Photovoltages and their gradients close to surface affect the emission yield and the detection efficiency of secondary electrons (SE), leading to photoexcited SE 2D patterns. In this work, we present a method to characterize the evolution of the patterns up to ultrafast regime. These results reveal the role of surface states in affecting the external field dynamics at picoseconds. Moreover, we show that tiny changes in surface preparation express deeply different photoexcited voltage signals. We investigate the relation between the surface chemistry of Si and photo-induced SE contrast.

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Quantitative material analysis using secondary electron energy spectromicroscopy

Cited by 14 publications

References 80 publications

Carbon Capture Potential in Lime Modified Kaolin Clay

Carbon Capture Potential in Lime Modified Kaolin Clay

Monitoring Carbon in Electron and Ion Beam Deposition within FIB-SEM

Dynamical imaging of local photovoltage at semiconductor surface by photo-assisted ultrafast scanning electron microscopy

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