Spectro-Mechanical Characterizations of Kerogen Heterogeneity and Mechanical Properties of Source Rocks at 6 nm Spatial Resolution

Jakob, Devon S.; Wang, Le; Wang, Haomin; Xu, Xiaoji G.

doi:10.1021/acs.analchem.9b00264

Cited by 43 publications

(45 citation statements)

References 60 publications

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“…This suggests that an upper limit on the resolution of the TAP525 is set at 25 GPa kerogen. The different mean moduli between samples probably reflect chemical differences in OM, supported by observations by Jakob et al (2019) who showed that there is significant chemo-mechanical variation even within a single sample. The effects of OM chemistry on mechanical properties are still an open question (Li et al 2018b, a;Goodarzi 2018), although some preliminary work has been done by Emmanuel et al (2016), who suggest that increasing maturity causes stiffening in organic material.…”

Section: Organic Mattersupporting

confidence: 55%

“…Such intra-sample variability therefore precludes inter-sample comparison unless the repeatability of AFM measurements can be demonstrated. The results of Jakob et al (2019) show that mechanical differences between OM in shales that are equally mature from the perspective of RockEval may still yield mechanical differences at the nanoscale that are the result of maturity-related heterogeneity. Therefore, demonstrating the repeatability of AFM results is crucial to interpret their mechanics reliably.…”

Section: Introductionmentioning

confidence: 95%

“…Various studies of OM in shale cite other studies to validate their results. However, Jakob et al (2019) have shown that intra-sample geochemical composition can vary significantly at the nanoscale. Such intra-sample variability therefore precludes inter-sample comparison unless the repeatability of AFM measurements can be demonstrated.…”

Section: Introductionmentioning

confidence: 99%

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Geomechanical characterisation of organic-rich calcareous shale using AFM and nanoindentation

et al. 2020

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The geomechanical integrity of shale overburden is a highly significant geological risk factor for a range of engineering and energy-related applications including CO$$_2$$ 2 storage and unconventional hydrocarbon production. This paper aims to provide a comprehensive set of high-quality nano- and micro-mechanical data on shale samples to better constrain the macroscopic mechanical properties that result from the microstructural constituents of shale. We present the first study of the mechanical responses of a calcareous shale over length scales of 10 nm to 100 $$\upmu$$ μ m, combining approaches involving atomic force microscopy (AFM), and both low-load and high-load nanoindentation. PeakForce quantitative nanomechanical mapping AFM (PF-QNM) and quantitative imaging (QI-AFM) give similar results for Young’s modulus up to 25 GPa, with both techniques generating values for organic matter of 5–10 GPa. Of the two AFM techniques, only PF-QNM generates robust results at higher moduli, giving similar results to low-load nanoindentation up to 60 GPa. Measured moduli for clay, calcite, and quartz-feldspar are $$22 \pm 2\,\hbox { GPa}$$ 22 ± 2 GPa , $$42 \pm 8\,\hbox { GPa}$$ 42 ± 8 GPa , and $$55 \pm 10\,\hbox { GPa}$$ 55 ± 10 GPa respectively. For calcite and quartz-feldspar, these values are significantly lower than measurements made on highly crystalline phases. High-load nanoindentation generates an unimodal mechanical response in the range of 40–50 GPa for both samples studied here, consistent with calcite being the dominant mineral phase. Voigt and Reuss bounds calculated from low-load nanoindentation results for individual phases generate the expected composite value measured by high-load nanoindentation at length scales of 100–600 $$\upmu$$ μ m. In contrast, moduli measured on more highly crystalline mineral phases using data from literature do not match the composite value. More emphasis should, therefore, be placed on the use of nano- and micro-scale data as the inputs to effective medium models and homogenisation schemes to predict the bulk shale mechanical response.

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Section: Organic Mattersupporting

confidence: 55%

Section: Introductionmentioning

confidence: 95%

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Geomechanical characterisation of organic-rich calcareous shale using AFM and nanoindentation

et al. 2020

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“…This method has been demonstrated on a variety of samples to provide spectroscopic imaging with a spatial resolution as high as 6 nm, as well as complimentary nano-mechanical information. [20,22] In this communication, we show that PFIR microscopy is a competitive imaging method for studying 2D polaritonic materials. PhPs of hexagonal boron nitride (h-BN) were revealed, and their dispersion relations were extracted, similar to studying h-BN by using the imaging capability of s-SNOM.…”

mentioning

confidence: 78%

“…PFIR microscopy operates in the peak force tapping mode that can avoid sample damage. This method has been demonstrated on a variety of samples to provide spectroscopic imaging with a spatial resolution as high as 6 nm, as well as complimentary nano‐mechanical information …”

mentioning

confidence: 99%

Revealing Phonon Polaritons in Hexagonal Boron Nitride by Multipulse Peak Force Infrared Microscopy

Wang

Wagner

Wang

et al. 2019

Advanced Optical Materials

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Probing of polaritons in 2D materials is facilitated by spectroscopic imaging with nanometer spatial resolution. The combination of atomic force microscopy and infrared laser sources provides access for in situ mappings of phonon polaritons. Here, it is demonstrated that the photothermal‐based peak force infrared microscopy is capable of revealing phonon polaritons with high spatial resolution in isotopically pure hexagonal boron nitride microstructures without damaging the sample. To further improve the sensitivity, peak force infrared microscopy is enhanced with a scheme of multiple laser pulse excitation. The resulting method of multipulse peak force infrared microscopy can detect phonon polaritons with high sensitivity, which is particularly useful for probing polaritons in 2D materials with high damping characteristics.

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Peak Force Infrared–Kelvin Probe Force Microscopy

et al. 2020

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Correlative scanning probe microscopy of chemical identity, surface potential, and mechanical properties provide insight into the structure–function relationships of nanomaterials. However, simultaneous measurement with comparable and high resolution is a challenge. We seamlessly integrated nanoscale photothermal infrared imaging with Coulomb force detection to form peak force infrared–Kelvin probe force microscopy (PFIR‐KPFM), which enables simultaneous nanomapping of infrared absorption, surface potential, and mechanical properties with approximately 10 nm spatial resolution in a single‐pass scan. MAPbBr3 perovskite crystals of different degradation pathways were studied in situ. Nanoscale charge accumulations were observed in MAPbBr3 near the boundary to PbBr2. PFIR‐KPFM also revealed correlations between residual charges and secondary conformation in amyloid fibrils. PFIR‐KPFM is applicable to other heterogeneous materials at the nanoscale for correlative multimodal characterizations.

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Spectro-Mechanical Characterizations of Kerogen Heterogeneity and Mechanical Properties of Source Rocks at 6 nm Spatial Resolution

Cited by 43 publications

References 60 publications

Geomechanical characterisation of organic-rich calcareous shale using AFM and nanoindentation

Geomechanical characterisation of organic-rich calcareous shale using AFM and nanoindentation

Revealing Phonon Polaritons in Hexagonal Boron Nitride by Multipulse Peak Force Infrared Microscopy

Peak Force Infrared–Kelvin Probe Force Microscopy

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