Fast, quantitative and high resolution mapping of viscoelastic properties with bimodal AFM.
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[1] Y. Ekinci,et al. Nano-confinement of block copolymers in high accuracy topographical guiding patterns: modelling the emergence of defectivity due to incommensurability. , 2018, Soft matter.
[2] Ricardo Garcia,et al. Fast and high-resolution mapping of elastic properties of biomolecules and polymers with bimodal AFM , 2018, Nature Protocols.
[3] Ricardo Garcia,et al. Theory of phase spectroscopy in bimodal atomic force microscopy , 2009 .
[4] P. Attard. Measurement and interpretation of elastic and viscoelastic properties with the atomic force microscope , 2007 .
[5] Ricardo Garcia,et al. Tip-surface forces, amplitude, and energy dissipation in amplitude-modulation (tapping mode) force microscopy , 2001 .
[6] Ricardo Garcia,et al. Theoretical study of the frequency shift in bimodal FM-AFM by fractional calculus , 2012, Beilstein journal of nanotechnology.
[7] R. Proksch,et al. Loss tangent imaging: Theory and simulations of repulsive-mode tapping atomic force microscopy , 2012 .
[8] R. Magerle,et al. Unraveling capillary interaction and viscoelastic response in atomic force microscopy of hydrated collagen fibrils. , 2017, Nanoscale.
[9] Guillaume Lamour,et al. High intrinsic mechanical flexibility of mouse prion nanofibrils revealed by measurements of axial and radial Young's moduli. , 2014, ACS nano.
[10] Ricardo Garcia,et al. Nanomechanical mapping of soft matter by bimodal force microscopy , 2013 .
[11] Á. S. Paulo,et al. High-resolution imaging of antibodies by tapping-mode atomic force microscopy: attractive and repulsive tip-sample interaction regimes. , 2000, Biophysical journal.
[12] A. Knoll,et al. Thermal scanning probe lithography for the directed self-assembly of block copolymers , 2017, Nanotechnology.
[13] F. Rico,et al. High-frequency microrheology reveals cytoskeleton dynamics in living cells , 2017, Nature Physics.
[14] Jiangyu Li,et al. Mapping the elastic properties of two-dimensional MoS2 via bimodal atomic force microscopy and finite element simulation , 2018, npj Computational Materials.
[15] G. Charras,et al. The cytoplasm of living cells behaves as a poroelastic material , 2013, Nature materials.
[16] Matteo Chiesa,et al. A method to provide rapid in situ determination of tip radius in dynamic atomic force microscopy. , 2012, The Review of scientific instruments.
[17] Ricardo Garcia,et al. How soft is a single protein? The stress-strain curve of antibody pentamers with 5 pN and 50 pm resolutions. , 2016, Nanoscale.
[18] S. Solares. Nanoscale effects in the characterization of viscoelastic materials with atomic force microscopy: coupling of a quasi-three-dimensional standard linear solid model with in-plane surface interactions , 2016, Beilstein journal of nanotechnology.
[19] A Tanaka,et al. Spin state transition in LaCoO3 studied using soft x-ray absorption spectroscopy and magnetic circular dichroism. , 2006, Physical review letters.
[20] A. Romero,et al. InN thin film lattice dynamics by grazing incidence inelastic x-ray scattering. , 2011, Physical review letters.
[21] S. Solares,et al. Bimodal atomic force microscopy driving the higher eigenmode in frequency-modulation mode: Implementation, advantages, disadvantages and comparison to the open-loop case , 2013, Beilstein journal of nanotechnology.
[22] Ricardo Garcia,et al. Dynamic force microscopy simulator (dForce): A tool for planning and understanding tapping and bimodal AFM experiments , 2015, Beilstein journal of nanotechnology.
[23] S. Solares,et al. Probing viscoelastic surfaces with bimodal tapping-mode atomic force microscopy: Underlying physics and observables for a standard linear solid model , 2014, Beilstein journal of nanotechnology.
[24] Ricardo Garcia,et al. Fast nanomechanical spectroscopy of soft matter , 2014, Nature Communications.
[25] Andreas Janshoff,et al. Atomic force microscopy-based microrheology reveals significant differences in the viscoelastic response between malign and benign cell lines , 2014, Open Biology.
[26] Z. Al-Rekabi,et al. Multifrequency AFM reveals lipid membrane mechanical properties and the effect of cholesterol in modulating viscoelasticity , 2018, Proceedings of the National Academy of Sciences.
[27] C. Dietz. Sensing in-plane nanomechanical surface and sub-surface properties of polymers: local shear stress as function of the indentation depth. , 2018, Nanoscale.
[28] Arvind Raman,et al. Measuring nanoscale viscoelastic parameters of cells directly from AFM force-displacement curves , 2017, Scientific Reports.
[29] V. Tsukruk,et al. Probing of polymer surfaces in the viscoelastic regime. , 2014, Langmuir : the ACS journal of surfaces and colloids.
[30] Arvind Raman,et al. VEDA: a web-based virtual environment for dynamic atomic force microscopy. , 2008, The Review of scientific instruments.
[31] O. Gutfleisch,et al. Direct Measurement of the Magnetocaloric Effect in La (Fe ,Si ,Co ) 13 Compounds in Pulsed Magnetic Fields , 2017 .
[32] W. T. Cruz,et al. Analytical model of atomic-force-microscopy force curves in viscoelastic materials exhibiting power law relaxation , 2016, 1610.07180.
[33] Ricardo Garcia,et al. The emergence of multifrequency force microscopy. , 2012, Nature nanotechnology.
[34] T. Nishi,et al. True Surface Topography and Nanomechanical Mapping Measurements on Block Copolymers with Atomic Force Microscopy , 2010 .
[35] F. Biscarini,et al. Morphological and mechanical properties of alkanethiol Self-Assembled Monolayers investigated via BiModal Atomic Force Microscopy. , 2011, Chemical communications.
[36] Makiko Ito,et al. Elastic and viscoelastic characterization of inhomogeneous polymers by bimodal atomic force microscopy , 2016 .
[37] Ricardo Garcia,et al. Compositional mapping of surfaces in atomic force microscopy by excitation of the second normal mode of the microcantilever , 2004 .
[38] Matteo Chiesa,et al. Systematic Multidimensional Quantification of Nanoscale Systems From Bimodal Atomic Force Microscopy Data. , 2016, ACS nano.
[39] F. Stellacci,et al. Bimodal atomic force microscopy for the characterization of thiolated self-assembled monolayers. , 2018, Nanoscale.
[40] A. Knoll,et al. Tapping mode atomic force microscopy on polymers: Where is the true sample surface? , 2001 .
[41] J. Faraudo,et al. Long-lived ionic nano-domains can modulate the stiffness of soft interfaces. , 2019, Nanoscale.
[42] Abdullah Atalar,et al. Force spectroscopy using bimodal frequency modulation atomic force microscopy , 2011 .
[43] Ricardo Garcia,et al. Theory of multifrequency atomic force microscopy. , 2008, Physical review letters.
[44] Makiko Ito,et al. Direct Mapping of Nanoscale Viscoelastic Dynamics at Nanofiller/Polymer Interfaces , 2018, Macromolecules.
[45] Arvind Raman,et al. Fast, multi-frequency, and quantitative nanomechanical mapping of live cells using the atomic force microscope , 2015, Scientific Reports.
[46] Ricardo Garcia,et al. Time-resolved nanomechanics of a single cell under the depolymerization of the cytoskeleton. , 2017, Nanoscale.
[47] Ricardo Garcia,et al. Mapping Elastic Properties of Heterogeneous Materials in Liquid with Angstrom-Scale Resolution. , 2017, ACS nano.
[48] B. Rothen‐Rutishauser,et al. Probing nano-scale viscoelastic response in air and in liquid with dynamic atomic force microscopy. , 2018, Soft matter.
[49] Calibration of higher eigenmodes of cantilevers. , 2016, The Review of scientific instruments.
[50] S. Solares,et al. Energy transfer between eigenmodes in multimodal atomic force microscopy , 2014, Nanotechnology.
[51] Z. Puthucheary,et al. A Study of Perturbations in Structure and Elastic Modulus of Bone Microconstituents Using Bimodal Amplitude Modulated-Frequency Modulated Atomic Force Microscopy. , 2018, ACS biomaterials science & engineering.
[52] Roger Proksch,et al. Fast, High Resolution, and Wide Modulus Range Nanomechanical Mapping with Bimodal Tapping Mode. , 2017, ACS nano.
[53] Ricardo Garcia,et al. Attractive and repulsive tip-sample interaction regimes in tapping-mode atomic force microscopy , 1999 .
[54] Vahid Vahdat,et al. Practical method to limit tip-sample contact stress and prevent wear in amplitude modulation atomic force microscopy. , 2013, ACS nano.
[55] Ernst Meyer,et al. Systematic achievement of improved atomic-scale contrast via bimodal dynamic force microscopy. , 2009, Physical review letters.
[56] M. Viani,et al. Practical loss tangent imaging with amplitude-modulated atomic force microscopy , 2016 .
[57] Ricardo Garcia,et al. Determination of the Elastic Moduli of a Single Cell Cultured on a Rigid Support by Force Microscopy. , 2018, Biophysical journal.
[58] E. Meyer,et al. Ultrasensitive detection of lateral atomic-scale interactions on graphite (0001) via bimodal dynamic force measurements , 2010 .
[59] E. Riedo,et al. Advanced scanning probe lithography. , 2014, Nature nanotechnology.
[60] A. Raman,et al. Dynamic AFM on Viscoelastic Polymer Samples with Surface Forces , 2018, Macromolecules.
[61] T. Russell,et al. Advances in Atomic Force Microscopy for Probing Polymer Structure and Properties , 2018 .
[62] Enrique A. López-Guerra,et al. Theory of Single-Impact Atomic Force Spectroscopy in liquids with material contrast , 2018, Scientific Reports.
[63] J. Gómez‐Herrero,et al. Noninvasive protein structural flexibility mapping by bimodal dynamic force microscopy. , 2011, Physical review letters.
[64] W. Meinhold,et al. Generalized Hertz model for bimodal nanomechanical mapping , 2016, Beilstein journal of nanotechnology.
[65] D. Ginger,et al. Electrochemical strain microscopy probes morphology-induced variations in ion uptake and performance in organic electrochemical transistors. , 2017, Nature materials.