Your search keyword '"Ferry Kienberger"' showing total 5 results

1. Accuracy Estimation in Force Spectroscopy Experiments

Author

Peter Hinterdorfer, Hermann J. Gruber, Christian Rankl, Ferry Kienberger, and Dieter Blaas

Subjects

Length scale, Physics and Astronomy (miscellaneous), Chemistry, Estimation theory, Monte Carlo method, General Engineering, Force spectroscopy, Analytical chemistry, General Physics and Astronomy, Thermodynamics, Derivative, Kinetic energy, Experimental system, Bootstrapping (statistics)

Abstract

Force spectroscopy is a useful tool for the investigation of molecular interactions. We here present a detailed analysis of parameter estimation in force spectroscopy experiments. It provides the values of the statistical errors of the kinetic off-rate constant koff and the energy length scale xβ to be considered using the single barrier model. As a biologically relevant experimental system we used the interaction between human rhinovirus serotype 2 and a recombinant derivative of the very-low density lipoprotein receptor. The interaction forces of single virus–receptor pairs were measured at different loading rates and analysed according to the single barrier model. Accuracy estimates of koff and xβ were obtained by Monte Carlo simulation and bootstrapping. For this model of virus–receptor attachment, force spectroscopy experiments yielded xβ=(0.38±0.07) nm and ln koff=(-2.3±1.0)ln s-1.

Published

2007

2. Corrigendum: Calibrated complex impedance and permittivity measurements with scanning microwave microscopy (2014 Nanotechnology 25 145703)

Author

Gabriel Gomila, Laura Fumagalli, Peter Hinterdorfer, Manuel Kasper, Ferry Kienberger, and Georg Gramse

Subjects

010302 applied physics, Permittivity, Materials science, Mechanical Engineering, Bioengineering, Nanotechnology, 02 engineering and technology, General Chemistry, 021001 nanoscience & nanotechnology, 01 natural sciences, Mechanics of Materials, 0103 physical sciences, Microscopy, General Materials Science, Electrical and Electronic Engineering, 0210 nano-technology, Electrical impedance, Microwave

Published

2015

3. Quantitative sub-surface and non-contact imaging using scanning microwave microscopy

Author

Manuel Kasper, Romolo Marcelli, Georg Gramse, Samadhan B. Patil, Andrea Lucibello, Peter Hinterdorfer, Enrico Brinciotti, Christian Rankl, Ferry Kienberger, and Rajiv Giridharagopal

Subjects

Scanning microwave microscopy, Materials science, Silicon, Capacitance, chemistry.chemical_element, Bioengineering, Complex impedance, Optics, Microscopy, Nanotechnology, General Materials Science, Sensitivity (control systems), Electrical and Electronic Engineering, Sub-surface imaging, Dopant, business.industry, Mechanical Engineering, General Chemistry, Radius, chemistry, Mechanics of Materials, Calibration, business, Layer (electronics), Microwave

Abstract

The capability of scanning microwave microscopy for calibrated sub-surface and non-contact capacitance imaging of silicon (Si) samples is quantitatively studied at broadband frequencies ranging from 1 to 20 GHz. Calibrated capacitance images of flat Si test samples with varying dopant density (10(15)-10(19) atoms cm(-3)) and covered with dielectric thin films of SiO2 (100-400 nm thickness) are measured to demonstrate the sensitivity of scanning microwave microscopy (SMM) for sub-surface imaging. Using standard SMM imaging conditions the dopant areas could still be sensed under a 400 nm thick oxide layer. Non-contact SMM imaging in lift-mode and constant height mode is quantitatively demonstrated on a 50 nm thick SiO2 test pad. The differences between non-contact and contact mode capacitances are studied with respect to the main parameters influencing the imaging contrast, namely the probe tip diameter and the tip-sample distance. Finite element modelling was used to further analyse the influence of the tip radius and the tip-sample distance on the SMM sensitivity. The understanding of how the two key parameters determine the SMM sensitivity and quantitative capacitances represents an important step towards its routine application for non-contact and sub-surface imaging.

Published

2015

4. Calibrated complex impedance of CHO cells and E. coli bacteria at GHz frequencies using scanning microwave microscopy.

Author

Silviu-Sorin Tuca, Giorgio Badino, Georg Gramse, Enrico Brinciotti, Manuel Kasper, Yoo Jin Oh, Rong Zhu, Christian Rankl, Peter Hinterdorfer, and Ferry Kienberger

Subjects

ELECTRIC properties of solids, BACTERIA, OVARIES, ELECTRIC admittance, PERMITTIVITY

Abstract

The application of scanning microwave microscopy (SMM) to extract calibrated electrical properties of cells and bacteria in air is presented. From the S11 images, after calibration, complex impedance and admittance images of Chinese hamster ovary cells and E. coli bacteria deposited on a silicon substrate have been obtained. The broadband capabilities of SMM have been used to characterize the bio-samples between 2 GHz and 20 GHz. The resulting calibrated cell and bacteria admittance at 19 GHz were Ycell = 185 μS + j285 μS and Ybacteria = 3 μS + j20 μS, respectively. A combined circuitry-3D finite element method EMPro model has been developed and used to investigate the frequency response of the complex impedance and admittance of the SMM setup. Based on a proposed parallel resistance–capacitance model, the equivalent conductance and parallel capacitance of the cells and bacteria were obtained from the SMM images. The influence of humidity and frequency on the cell conductance was experimentally studied. To compare the cell conductance with bulk water properties, we measured the imaginary part of the bulk water loss with a dielectric probe kit in the same frequency range resulting in a high level of agreement. [ABSTRACT FROM AUTHOR]

Published

2016

5. Quantitative sub-surface and non-contact imaging using scanning microwave microscopy.

Author

Georg Gramse, Enrico Brinciotti, Andrea Lucibello, Samadhan B. Patil, Manuel Kasper, Christian Rankl, Rajiv Giridharagopal, Peter Hinterdorfer, Romolo Marcelli, and Ferry Kienberger

Subjects

ELECTRIC properties of silicon, ELECTRIC capacity, MICROWAVE measurements, DIELECTRIC thin films, FINITE element method, NANOTECHNOLOGY

Abstract

The capability of scanning microwave microscopy for calibrated sub-surface and non-contact capacitance imaging of silicon (Si) samples is quantitatively studied at broadband frequencies ranging from 1 to 20 GHz. Calibrated capacitance images of flat Si test samples with varying dopant density (1015–1019 atoms cm−3) and covered with dielectric thin films of SiO2 (100–400 nm thickness) are measured to demonstrate the sensitivity of scanning microwave microscopy (SMM) for sub-surface imaging. Using standard SMM imaging conditions the dopant areas could still be sensed under a 400 nm thick oxide layer. Non-contact SMM imaging in lift-mode and constant height mode is quantitatively demonstrated on a 50 nm thick SiO2 test pad. The differences between non-contact and contact mode capacitances are studied with respect to the main parameters influencing the imaging contrast, namely the probe tip diameter and the tip–sample distance. Finite element modelling was used to further analyse the influence of the tip radius and the tip–sample distance on the SMM sensitivity. The understanding of how the two key parameters determine the SMM sensitivity and quantitative capacitances represents an important step towards its routine application for non-contact and sub-surface imaging. [ABSTRACT FROM AUTHOR]

Published

2015