Linear elastic contact of the Weierstrass profile

Ciavarella, M.; Demelio, G.; Barber, J. R.; Jang, Yong Hoon

doi:10.1098/rspa.2000.0522

Cited by 204 publications

(178 citation statements)

References 20 publications

(29 reference statements)

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“…Most surfaces are rough enough that atoms are only close enough to interact strongly in areas where peaks or asperities on opposing surfaces overlap. Experiments [1,2,3,4] and theory [5,6,7,8,9,10,11,12] show that this real area of contact A is often much smaller than the projected area A 0 of the surfaces. They have also correlated [1,2,3] the increase in friction with normal load W to a corresponding increase in A.…”

Section: Introductionmentioning

confidence: 99%

Finite-element analysis of contact between elastic self-affine surfaces

et al. 2004

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Finite element methods are used to study non-adhesive, frictionless contact between elastic solids with self-affine surfaces. We find that the total contact area rises linearly with load at small loads. The mean pressure in the contact regions is independent of load and proportional to the rms slope of the surface. The constant of proportionality is nearly independent of Poisson ratio and roughness exponent and lies between previous analytic predictions. The contact morphology is also analyzed. Connected contact regions have a fractal area and perimeter. The probability of finding a cluster of area ac drops as a −τ c where τ increases with decreasing roughness exponent. The distribution of pressures shows an exponential tail that is also found in many jammed systems. These results are contrasted to simpler models and experiment.

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Section: Introductionmentioning

confidence: 99%

Finite-element analysis of contact between elastic self-affine surfaces

et al. 2004

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“…Motivated by the recent work in [3], we have carried out an elastic-plastic contact analysis of a fractal rough surface, which is idealized with a Weierstrass series. Scaling relations of the total contact area versus the applied load and roughness properties can be deduced [4], and compared with numerical simulations that have pre-specified spatial cutoff sizes [5,6].…”

Section: Introductionmentioning

confidence: 99%

Some Issues of Rough Surface Contact Plasticity at Micro- and Nano-Scales

2004

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Rough surface contact plasticity at microscale and nanoscale is of crucial importance in many new applications and technologies, such as nano-imprinting and nano-welding. This paper summarizes our recent progress in understanding contact plasticity from a multiscale point of view, and also presents our perspectives. We first discuss a contact model based on fractal roughness and continuum plasticity theory. Interestingly, our simple, elastic-plastic contact model of Weierstrass-Archard type gives rise to many practical scaling relations of contact pressure, contact compliance etc. The usefulness of those predictions is discussed for the experiments of indentation and measurements of thermal and electrical properties. A material length scale can be introduced by a nonlocal plasticity theory, or implicitly by dislocation mechanics model. The recent work on micro-plasticity of surface steps gives a variety of surface yielding and hardening behaviors, depending on interface adhesion, roughness features and slip systems. As a consequence, a rough surface contact at small scale can lead to the formation of a boundary layer with sub-layer dislocation structures, which cannot be predicted by existing strain gradient plasticity theories. The micromechanical analysis of surface plasticity could serve as the connection between microscale bulk dislocation plasticity and nanoscale atomistic simulations.

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“…In an attempt to solve the paradoxes of Ciavarella et al [4], Gao et al [19] added plasticity in the Weierstrass model. While the elastic model [4] showed that the -fractal limit‖ consists of an infinite number of contact spots, with zero size, subjected to infinite contact pressure, Gao et al [19]'s model found that while the total contact area and contact pressure are well defined, it remains impossible to predict the actual number of contacts or their size. They also suggest to add adhesion (but the problem with both plasticity and adhesion has not even been attempted yet) or truncating the fractal process where the fractal description breaks down.…”

Section: Plasticity Modelsmentioning

confidence: 99%

“…In fact, he even anticipated -fractals‖ which were much later used in a more refined form in the -contact sport‖ of rough surfaces. Yet it was only much later that Ciavarella et al [4] remarked that linearity involves a linear coefficient which is scale-dependent, and in particular it goes to zero for realistic fractal geometry. This was done with the not very popular choice of a Weierstrass series as a fractal, but later Gaussian model theories [5] did not change the basic conclusion that -no applied mean pressure is sufficiently large to ensure full contact and indeed there are not even any contact areas of finite dimension -the contact area consists of a set of fractal character for all values of the geometric and loading parameters‖.…”

Section: Introductionmentioning

confidence: 99%