Enhanced dielectric constant resolution of thin insulating films by electrostatic force microscopy

Castellano‐Hernández, Elena; Moreno-Llorena, Jaime; Sáenz, J. J.; Sacha, G. M.

doi:10.1088/0953-8984/24/15/155303

Cited by 10 publications

(9 citation statements)

References 21 publications

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“…Both the metallic and Air/vacuum limits correspond to a tip over a metallic sample with different tip-sample distances (D and D+h respectively). The behaviour of the force is well known for metallic samples 21 . Taken into account these previous results and the boundary conditions of a dielectric plate, a simple expression can be deduced for the electrostatic force:…”

Section: Theoretical Simulationsmentioning

confidence: 98%

A Model for the Characterization of the Polarizability of Thin Films Independently of the Thickness of the Film

2017

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The dielectric properties of thin films can be modified relative to the bulk material because the interaction between film and substrate influences the mobility of the atoms or molecules in the first layers. Here we show that a strong scale effect occurs in nanometer size octadecylammine thin films. This effect is attributed to the different distribution of molecules depending on the size of the film. To accurately describe this effect, we have developed a model which is a reinterpretation of the linearized Thomas-Fermi approximation. Within this model, we have been able to characterize the polarizability of thin films independently of the thickness of the film.

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Section: Theoretical Simulationsmentioning

confidence: 98%

A Model for the Characterization of the Polarizability of Thin Films Independently of the Thickness of the Film

2017

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“…[9] In the case of thin films, it has been also shown that the substrate thickness and dielectric constant are key parameters for a quantitative characterization. [10] Some effects like the detection of effective ultrahigh dielectric constants due, for example, to the presence of certain conductivity in the thin film can be also present. [11] In the EFM setup proposed in this article, there are at least three layers that could modify the magnitude and behaviour of the electrostatic force.…”

Section: mentioning

confidence: 99%

“…The details of this method, including a three layers thin film sample have been described elsewhere 10 and only a brief description is given here. Basically, the GICM can be understood by a method that includes the sample and tip shape in two steps.…”

Section: Theoretical Backgroundmentioning

confidence: 99%

Influence of the Substrate and Tip Shape on the Characterization of Thin Films by Electrostatic Force Microscopy

Sacha

2013

IEEE Trans. Nanotechnology

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Esta es la versión de autor del artículo publicado en: This is an author produced version of a paper published in: G. M. SachaAbstract-Electrostatic force microscopy has been shown to be a useful tool to determine the dielectric constant of nanoscaled thin films that play a key role in many electrical, optical and biological phenomena. Previous approaches have made use of simple analytical models to analyze the experimental data for these materials. Here we show that the electrostatic force shows a completely different behavior when the shape of the tip and sample are taken into account. We present a complete study of the interaction between the whole tip and the layers below the thin film. We demonstrate that physical magnitudes such as the surface charge density distribution and the size of the materials have a strong influence on the EFM signal. The EFM sensitivity to the substrate below the thin film decreases with the substrate thickness and saturates for thicknesses above two times the length of the tip, when it is close to that of an infinite medium.

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“…These technical improvements have been especially relevant in the characterization of thin films [7][8][9][10]. Most of the previous work has been focused on perfectly insulating dielectrics [11], but the possible effect of a small conductivity on the EFM signal has not been addressed before (i.e., previously, every layer included in the sample was only characterized by the thickness and dielectric constant). The conductivity, even with small values, is very important in the characterization of thin films in air ambient conditions where water and molecular adsorption and water condensation [12][13][14] can be detected as a finite surface conductivity due to the ions added on the otherwise insulating sample.…”

Section: Introductionmentioning

confidence: 99%

Finite Conductivity Effects in Electrostatic Force Microscopy on Thin Dielectric Films: A Theoretical Model

Castellano‐Hernández

Sacha

2015

Advances in Condensed Matter Physics

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A study of the electrostatic force between an Electrostatic Force Microscope tip and a dielectric thin film with finite conductivity is presented. By using the Thomas-Fermi approximation and the method of image charges, we calculate the electrostatic potential and force as a function of the thin film screening length, which is a magnitude related to the amount of free charge in the thin film and is defined as the maximum length that the electric field is able to penetrate in the sample. We show the microscope’s signal on dielectric films can change significantly in the presence of a finite conductivity even in the limit of large screening lengths. This is particularly relevant in determining the effective dielectric constant of thin films from Electrostatic Force Microscopy measurements. According to our model, for example, a small conductivity can induce an error of more than two orders of magnitude in the determination of the dielectric constant of a material. Finally, we suggest a method to discriminate between permittivity and conductivity effects by analyzing the dependence of the signal with the tip-sample distance.

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Enhanced dielectric constant resolution of thin insulating films by electrostatic force microscopy

Cited by 10 publications

References 21 publications

A Model for the Characterization of the Polarizability of Thin Films Independently of the Thickness of the Film

A Model for the Characterization of the Polarizability of Thin Films Independently of the Thickness of the Film

Influence of the Substrate and Tip Shape on the Characterization of Thin Films by Electrostatic Force Microscopy

Finite Conductivity Effects in Electrostatic Force Microscopy on Thin Dielectric Films: A Theoretical Model

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