Internal interface diversification as a method against malware

Abstract. An elastic structure subjected to thermal and mechanical loading with prescribed external boundary and varying internal interface is considered. The different thermal and mechanical nature of this interface is discussed, since the interface form and its properties affect strongly the structural response. The first-order sensitivities of an arbitrary thermal and mechanical behavioral functional with respect to shape and material properties of the interface are derived using the direct or adjoint approaches. Next the relevant optimality conditions are formulated. Some examples illustrate the applicability of proposed approach to control the structural response due to applied thermal and mechanical loads.

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On the anisotropic response of a Janus drop in a shearing viscous fluid

Journal of Fluid Mechanics ◽

10.1017/jfm.2015.148 ◽

2015 ◽

Vol 770 ◽

Cited By ~ 3

Author(s):

Misael Díaz-Maldonado ◽

Ubaldo M. Córdova-Figueroa

Keyword(s):

Shear Flow ◽

Velocity Gradient ◽

External Flow ◽

Bodies Of Revolution ◽

Internal Interface ◽

Equal Radius ◽

Fluid Drop ◽

Resistance Matrix ◽

Shearing Motion ◽

Unbounded Fluid

The force and couple that result from the shearing motion of a viscous, unbounded fluid on a Janus drop are the subjects of this investigation. A pair of immiscible, viscous fluids comprise the Janus drop and render it with a ‘perfect’ shape: spherical with a flat, internal interface, in which each constituent fluid is bounded by a hemispherical domain of equal radius. The effect of the arrangement of the internal interface (drop orientation) relative to the unidirectional shear flow is explored within the Stokes regime. Projection of the external flow into a reference frame centred on the drop simplifies the analysis to three cases: (i) a shear flow with a velocity gradient parallel to the internal interface, (ii) a hyperbolic flow, and (iii) two shear flows with a velocity gradient normal to the internal interface. Depending on the viscosity of the internal fluids, the Janus drop behaves as a simple fluid drop or as a solid body with broken fore and aft symmetry. The resultant couple arises from both the straining and swirling motions of the external flow in analogy with bodies of revolution. Owing to the anisotropic resistance of the Janus drop, it is inferred that the drop can migrate lateral to the streamlines of the undisturbed shear flow. The grand resistance matrix and Bretherton constant are reported for a Janus drop with similar internal viscosities.

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Small Angle Neutron Scatitering Study of Sol-Gel Glasses

MRS Proceedings ◽

10.1557/proc-166-433 ◽

1989 ◽

Vol 166 ◽

Author(s):

P. Wiltzius ◽

S. B. Dierker

Keyword(s):

Neutron Scattering ◽

Small Angle ◽

Structure Factor ◽

Small Angle Neutron Scattering ◽

Sol Gel ◽

Scattering Data ◽

Length Scales ◽

Internal Interface ◽

Porous Glasses ◽

Gel Glasses

ABSTRACTWe present small angle neutron scattering data of porous glasses. Analysis of the structure factor shows that the morphology on length scales between 30 A and 800 A depends on fabrication procedures. Fast gelation leads to a clumpy glass, whereas slow gelation produces a random smooth internal interface.

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The internal interface of dental implants as a hotbed of chronic infection

Medical news of the North Caucasus ◽

10.14300/mnnc.2015.00073 ◽

2015 ◽

Vol 0 (3) ◽

Author(s):

Dmitriy Mihalchenko ◽

Evgeniy Badrak ◽

Alexey Mihalchenko ◽

Elena Yarigina

Keyword(s):

Dental Implants ◽

Chronic Infection ◽

Internal Interface

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Maintaining complex and distributed measurement systems with component internal interface framework

10.1117/12.838155 ◽

2009 ◽

Author(s):

Pawel Drabik ◽

Krzysztof T. Pozniak

Keyword(s):

Internal Interface ◽

Measurement Systems ◽

Distributed Measurement Systems ◽

Distributed Measurement

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Backstage (The Internal Interface)

THE EXPERIENCE: The 5 Principles of Disney Service and Relationship Excellence ◽

10.1002/9781119153795.part3 ◽

2015 ◽

pp. 225-226

Keyword(s):

Internal Interface

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The Gibbs-Thomson Equation

The Equations of Materials ◽

10.1093/oso/9780198851875.003.0006 ◽

2020 ◽

pp. 109-140

Author(s):

Brian Cantor

Keyword(s):

Natural Philosophy ◽

Bulk Material ◽

Equilibrium Shape ◽

Surface Adsorption ◽

Internal Interface ◽

Cambridge University ◽

The Third ◽

The World ◽

William Thomson ◽

Lord Kelvin

The external surface of a material has an atomic or molecular structure that is different from the bulk material. So does any internal interface within a material. Because of this, the energy of a material or any grain or particle within it increases with the curvature of its bounding surface, as described by the Gibbs-Thomson equation. This chapter explains how surfaces control the nucleation of new phases during reactions such as solidification and precipitation, the coarsening and growth of particles during heat treatment, the equilibrium shape of crystals, and the surface adsorption and segregation of solutes and impurities. The Gibbs-Thomson was predated by a number of related equations; it is not clear whether it is named after J. J. Thomson or William Thomson (Lord Kelvin); and it was not put into its current usual form until after Gibbs’, Thomson’s and Kelvin’s time. J. J. Thomson was the third Cavendish Professor of Physics at Cambridge University. He discovered the electron, which had a profound impact on the world, notably via Thomas Edison’s invention of the light bulb, and subsequent building of the world’s first electricity distribution network. William Thomson was Professor of Natural Philosophy at Glasgow University. He made major scientific developments, notably in thermodynamics, and he helped build the first trans-Atlantic undersea telegraph. Because of his scientific pre-eminence, the absolute unit of temperature, the degree Kelvin, is named after him.

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