Principles and Applications of Liquid‐Environment Atomic Force Microscopy

Abstract: has been devoted to these areas due to the appearance of divergent phenomena at different scales, such as macroscopic fluid dynamics, mesoscopic hydrogen bond network, and nanoscopic hydration layer. Especially, as the basis of numerous important but complex physicochemical processes, such as dissolution, crystallization, corrosion, catalysis, protein folding, and so on, [10][11][12][13][14][15] the research of the underlying mechanism and atomic dynamics at the solid-liquid interface call for characterization… Show more

“…The effective thickness of a flake depends on multiple factors such as presence of physisorbed organic molecules and other adsorbents, , air gaps at substrate–flake interfaces, as well as exerted pressure that can alter bond length and consequently the thickness . These along with differences in gradients of the attractive and lateral forces on the material and the substrate, and anomalies due to tip–sample interactions , are common causes for misinterpreting the thickness values using an AFM instrument, which might also be invasive especially in the more-accurate contact mode . Optical microscopy provides a simpler way for estimating the exfoliated flake’s layer number, and not the actual thickness, based on the color contrast. , However, it involves uncertainties at times due to dependence on human cognition.…”

“… 26 These along with differences in gradients of the attractive and lateral forces on the material and the substrate, 27 and anomalies due to tip–sample interactions 28 , 29 are common causes for misinterpreting the thickness values using an AFM instrument, which might also be invasive especially in the more-accurate contact mode. 30 Optical microscopy provides a simpler way for estimating the exfoliated flake’s layer number, and not the actual thickness, based on the color contrast. 21 , 31 However, it involves uncertainties at times due to dependence on human cognition.…”

Thickness Mapping and Layer Number Identification of Exfoliated van der Waals Materials by Fourier Imaging Micro-Ellipsometry

“…The effective thickness of a flake depends on multiple factors such as presence of physisorbed organic molecules and other adsorbents, , air gaps at substrate–flake interfaces, as well as exerted pressure that can alter bond length and consequently the thickness . These along with differences in gradients of the attractive and lateral forces on the material and the substrate, and anomalies due to tip–sample interactions , are common causes for misinterpreting the thickness values using an AFM instrument, which might also be invasive especially in the more-accurate contact mode . Optical microscopy provides a simpler way for estimating the exfoliated flake’s layer number, and not the actual thickness, based on the color contrast. , However, it involves uncertainties at times due to dependence on human cognition.…”

“… 26 These along with differences in gradients of the attractive and lateral forces on the material and the substrate, 27 and anomalies due to tip–sample interactions 28 , 29 are common causes for misinterpreting the thickness values using an AFM instrument, which might also be invasive especially in the more-accurate contact mode. 30 Optical microscopy provides a simpler way for estimating the exfoliated flake’s layer number, and not the actual thickness, based on the color contrast. 21 , 31 However, it involves uncertainties at times due to dependence on human cognition.…”

Thickness Mapping and Layer Number Identification of Exfoliated van der Waals Materials by Fourier Imaging Micro-Ellipsometry

“…[28][29][30] Elegant molecular simulations have also studied the capillary adhesion of nanotips. [31][32][33] The capillary force of a meniscus can significantly reduce the imaging quality or measurement accuracy; 17,34 Hence, a tip that could reduce the capillary force is preferred.…”

Shape optimization of a meniscus-adherent nanotip

Atomic force microscopy