The JKR-type adhesive contact problems for power-law shaped axisymmetric punches

Borodich, Feodor M.; Galanov, Boris A.; Suarez-Alvarez, Maria M.

doi:10.1016/j.jmps.2014.03.003

Cited by 54 publications

(29 citation statements)

References 61 publications

(109 reference statements)

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“…Although the approach was applied to a sphere described as a paraboloid of revolution z = r 2 /(2 R ), very far generalizations of the approach are possible. Recently, the approach has been extended to non-slipping boundary conditions [47], transversely isotropic solids [48] and the punches of arbitrary axisymmetric blunt shapes contacting elastic materials with rotational symmetry of their elastic properties [44]. It is attempted here to follow the original JKR approach as closely as possible, hence we denote as a 1 , P 0 and δ 2 the true values of the radius of adhesive contact, the external load and the displacement, respectively.…”

Section: Preliminariesmentioning

confidence: 99%

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Contact probing of stretched membranes and adhesive interactions: graphene and other two-dimensional materials

Borodich

Galanov

2016

Proc. R. Soc. A.

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Contact probing is the preferable method for studying mechanical properties of thin two-dimensional (2D) materials. These studies are based on analysis of experimental force–displacement curves obtained by loading of a stretched membrane by a probe of an atomic force microscope or a nanoindenter. Both non-adhesive and adhesive contact interactions between such a probe and a 2D membrane are studied. As an example of the 2D materials, we consider a graphene crystal monolayer whose discrete structure is modelled as a 2D isotropic elastic membrane. Initially, for contact between a punch and the stretched circular membrane, we formulate and solve problems that are analogies to the Hertz-type and Boussinesq frictionless contact problems. A general statement for the slope of the force–displacement curve is formulated and proved. Then analogies to the JKR (Johnson, Kendall and Roberts) and the Boussinesq–Kendall contact problems in the presence of adhesive interactions are formulated. General nonlinear relations among the actual force, displacements and contact radius between a sticky membrane and an arbitrary axisymmetric indenter are derived. The dimensionless form of the equations for power-law shaped indenters has been analysed, and the explicit expressions are derived for the values of the pull-off force and corresponding critical contact radius.

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Section: Preliminariesmentioning

confidence: 99%

“…For example, as the characteristic scale for a 3D adhesive contact problem, Borodich et al [47] took the radius a 1 of the contact region at P 0 =0. For 2D membranes, the dimensionless variables could be also specified using various characteristic scales, in particular, via the radius of the membrane.…”

Section: Adhesion To a Circular Graphene Monolayer Membranementioning

confidence: 99%

Contact probing of stretched membranes and adhesive interactions: graphene and other two-dimensional materials

Borodich

Galanov

2016

Proc. R. Soc. A.

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“…35 In the same year, Borodich provided another derivation of Galanov's solution; however, it was published much later. 36 Some recent results related to the generalization of JKR theory for axisymmetric adhesive contact problems have been reviewed by Borodich. 37 For the contact problems involving non-axisymmetric shapes, the absence of radial symmetry presents significant difficulty in the numerical simulation, because the number of nonlinear equations increases from N to N 2 , as discussed Sec.…”

Section: Models In Contact Mechanicsmentioning

confidence: 99%

Nanoindentation of compliant materials using Berkovich tips and flat tips

Jin

Ebenstein

2016

J. Mater. Res.

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“…These models include the JKR (JohnsonKendall-Roberts), DMT (Derjaguin-Muller-Toporov), and Maugis models [1,16]. The extension of the JKR approach to axisymmetric solids of arbitrary monomial shape f (r) = B d r d [17][18][19] shows that the shape of the probe can considerably affect the value of the force of adhesion. Here f is the shape of the probe, r the radial coordinate, d is the degree of the monom (parabola) and B d is a constant.…”

Section: Depth-sensing Indentation and Adhesive Contactmentioning

confidence: 99%

Evaluation of adhesive and elastic properties of materials by depth-sensing indentation of spheres

et al. 2012

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Work of adhesion is the crucial material parameter for application of theories of adhesive contact. It is usually determined by experimental techniques based on the direct measurements of pull-off force of a sphere. These measurements are unstable due to instability of the loaddisplacement diagrams at tension, and they can be greatly affected by roughness of contacting solids. We show how the values of work of adhesion and elastic contact modulus of materials may be quantified using a new indirect approach (the Borodich-Galanov (BG) method) based on an inverse analysis of a stable region of the force-displacements curve obtained from the depth-sensing indentation of a sphere into an elastic sample. Using numerical simulations it is shown that the BG method is simple and robust. The crucial difference between the proposed method and the standard direct experimental techniques is that the BG method may be applied only to compressive parts of the force-displacements curves. Finally, the work of adhesion and the elastic modulus F.M. Borodich ( ) · Mof soft polymer (polyvinylsiloxane) samples are extracted from experimental load-displacement diagrams.

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The JKR-type adhesive contact problems for power-law shaped axisymmetric punches

Cited by 54 publications

References 61 publications

Contact probing of stretched membranes and adhesive interactions: graphene and other two-dimensional materials

Contact probing of stretched membranes and adhesive interactions: graphene and other two-dimensional materials

Nanoindentation of compliant materials using Berkovich tips and flat tips

Evaluation of adhesive and elastic properties of materials by depth-sensing indentation of spheres

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