Nanocharacterization of the negative stiffness of ferroelectric materials

The mechanical properties of amorphous silicon carbonitride (a-SiC x N y ) films with various nitrogen content (y = 0-40 at.%) were investigated in situ at elevated temperatures up to 650°C in inert atmosphere. A SiC film was measured also at 700°C in air. The hardness and elastic modulus were evaluated using instrumented nanoindentation with thermally stable cubic boron nitride Berkovich indenter. Both the sample and the indenter were separately heated during the experiments to temperatures of 300, 500, and 650°C. Short duration high temperature creep tests (1200 s) of the films were also carried out. The results revealed that the room temperature hardness and elastic modulus deteriorate with the increase of the nitrogen content. Furthermore, the hardness of both the a-SiC and the a-SiCN films with lower nitrogen content at 300°C drops to approx. 77 % of the corresponding room temperature values, while it reduces to 69 % for the a-SiCN film with 40 at.% of nitrogen. Further increase of temperature is accompanied with minor reduction in hardness except for the a-SiCN film with highest nitrogen content, where the hardness decreases at a much faster rate. Upon heating up to 500°C, the elastic modulus of the a-SiCN film decreases, while it increases at 650°C due to the pronounced effect of short-range ordering. The steady-state creep rate increases at elevated temperatures and the a-SiC exhibits slower creep rates compared to the a-SiCN films. The value of the universal constant x = 7 relating the W p /W t and H/E * was established and its applicability was demonstrated. Analysis of the experimental indentation data suggests a theoretical limit of hardness to elastic modulus ratio of 0.143.

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Mechanical properties of amorphous silicon carbonitride thin films at elevated temperatures

Čtvrtlík

Al-Haik

Kulikovsky

2014

J Mater Sci

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A high compatibility SiOCN coating on stainless steel

Choi

2023

J Mater Sci

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Negative stiffness in ZrW2O8 inclusions as a result of thermal stress

Romao

White

2016

Applied Physics Letters

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Materials with negative stiffness, although inherently unstable in isolation, can be stabilized by external constraints, for example, by inclusion within a material with positive stiffness. We have identified ZrW2O8, a material with negative thermal expansion, as a candidate negative-stiffness material arising from its negative bulk modulus during a ferroelastic cubic–orthorhombic pressure-induced phase transition (PIPT). A hyperelastic constituent equation for this transition was developed and implemented in a finite-element model of ZrW2O8 inclusions in positive stiffness, positive thermal expansion matrices. In these matrices, thermal stress during cooling, originating from thermal expansion mismatch, would be sufficient to initiate the PIPT after small temperature drops. The subsequent progress of the PIPT depends strongly on the thermoelastic properties of the matrix, with stiff, low thermal expansion matrices stabilizing the transition state over broad temperature ranges, indicating that ZrW2O8 or materials with similar properties could be used as versatile negative-stiffness inclusion materials. The models were used to understand previous experiments on composites that include ZrW2O8.

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Nanocharacterization of the negative stiffness of ferroelectric materials

Cited by 4 publications

References 30 publications

Mechanical properties of amorphous silicon carbonitride thin films at elevated temperatures

Mechanical properties of amorphous silicon carbonitride thin films at elevated temperatures

A high compatibility SiOCN coating on stainless steel

Negative stiffness in ZrW2O8 inclusions as a result of thermal stress

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