Skip to main content

MultiScale Material Science for Energy and Environment

Logo MultiScale Material Science

MultiScale Materials Science for Energy and Environment

  • Home
  • The Lab
  • People
  • Publications
  • News / Events
  • GDRI
  • Home
  • The Lab
    • The Lab
    • Research
    • Education
    • Amazing People
    • Contact
  • People
  • Publications
  • News / Events
    • News
    • Seminars
    • Conferences
    • Winter School
  • GDRI
    • Presentation

Fracture scaling relations for scratch tests of axisymmetric shape

TitleFracture scaling relations for scratch tests of axisymmetric shape
Publication TypeJournal Article
Year of Publication2012
AuthorsAkono A-T, Ulm F-J
JournalJournal of the Mechanics and Physics of Solids
Volume60
Issue3
Pagination379 - 390
Date PublishedMar-2012
ISSN00225096
Abstract

Scratch testing and scratch test analysis continues to gain momentum in Applied Mechanics, due to the possibility offered by this method to assess fracture properties at very fine scales. In this paper, we derive general scratch force scaling relations for axisymmetric scratch probes defined by single variable monomial functions. These relations are used to define fracture criteria with and without consideration of the development of shear stresses at the probe–material interface. The approach is illustrated for common scratch probe geometries: conical probe, flat punch, and hemi-spherical probe. Application of the proposed method to micro-scratch tests on two materials (an aluminum alloy and a thermoplastic polymer) using a Rockwell probe (a conical probe ending in a hemi-spherical shape) illustrates the versatility of the approach: First, the scratch force-depth scaling relations provide a means to determine the degree of the homogeneous function characterizing the scratch probe. Second, the fracture criteria enable an experimental assessment of the fracture toughness. The good agreement between the fracture toughness determined by scratching and values reported in the open literature show the potential of the proposed method for determining fracture properties of materials at even smaller scales.

Fig.1. Axisymmetric scratch probe geometry

Fig.2. Scaling of the normalized fracture force and the perimeter function, β, of the…

Fig.3. Forces in three scratch tests on aluminum alloy 2024 (AA 2024) obtained with a…

Fig.4. Fracture toughness determination from the scratch response of AA 2024 with a…

Fig.5. Response and analysis of three scratch tests on a thermoplastic polymer (Delrin…

 
DOI10.1016/j.jmps.2011.12.009
Short TitleJournal of the Mechanics and Physics of Solids
  • DOI
  • BibTex
  • RIS

Login using Touchstone
  • MIT
  • CNRS
  • INVESTISSEMENT D'AVENIR
  • CINAM
  • MITEI
  • AMU