Interpretations of Indentation Size Effects

W. W.  Gerberich; M. F.  Horstemeyer; M. I.  Baskes; N. I.  Tymiak; J. C.  Grunlan

Source: Journal of Applied Mechanics:;2002:;volume( 069 ):;issue: 004::page 433

Author:

DOI: 10.1115/1.1469004

Publisher: The American Society of Mechanical Engineers (ASME)

Abstract: For very shallow indentations in W, Al, Au, and Fe-3wt%Si single crystals, hardness decreased with increasing depth irrespective of increasing or decreasing strain gradients. As such, strain gradient theory appears insufficient to explain the indentation size effect (ISE) at depths less than several hundred nanometers. Present research links the ISE to a ratio between the energy of newly created surface and plastic strain energy dissipation. Also, the contact surface to plastic volume ratio was nearly constant for a range of shallow depths. Based on the above, an analytical model of hardness versus depth provides a satisfactory fit to the experimental data and correlates well with embedded atom simulations.

keyword(s): Plasticity , Atoms , Crystals , Aluminum , Stress , Engineering simulation , Dislocations , Gradients , Size effect , Force , Energy dissipation , Flow (Dynamics) , Wedges , Yield stress AND Deformation ,

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Interpretations of Indentation Size Effects

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contributor author	W. W. Gerberich
contributor author	M. F. Horstemeyer
contributor author	M. I. Baskes
contributor author	N. I. Tymiak
contributor author	J. C. Grunlan
date accessioned	2017-05-09T00:06:37Z
date available	2017-05-09T00:06:37Z
date copyright	July, 2002
date issued	2002
identifier issn	0021-8936
identifier other	JAMCAV-26539#433_1.pdf
identifier uri	http://yetl.yabesh.ir/yetl/handle/yetl/126257
description abstract	For very shallow indentations in W, Al, Au, and Fe-3wt%Si single crystals, hardness decreased with increasing depth irrespective of increasing or decreasing strain gradients. As such, strain gradient theory appears insufficient to explain the indentation size effect (ISE) at depths less than several hundred nanometers. Present research links the ISE to a ratio between the energy of newly created surface and plastic strain energy dissipation. Also, the contact surface to plastic volume ratio was nearly constant for a range of shallow depths. Based on the above, an analytical model of hardness versus depth provides a satisfactory fit to the experimental data and correlates well with embedded atom simulations.
publisher	The American Society of Mechanical Engineers (ASME)
title	Interpretations of Indentation Size Effects
type	Journal Paper
journal volume	69
journal issue	4
journal title	Journal of Applied Mechanics
identifier doi	10.1115/1.1469004
journal fristpage	433
journal lastpage	442
identifier eissn	1528-9036
keywords	Plasticity
keywords	Atoms
keywords	Crystals
keywords	Aluminum
keywords	Stress
keywords	Engineering simulation
keywords	Dislocations
keywords	Gradients
keywords	Size effect
keywords	Force
keywords	Energy dissipation
keywords	Flow (Dynamics)
keywords	Wedges
keywords	Yield stress AND Deformation
tree	Journal of Applied Mechanics:;2002:;volume( 069 ):;issue: 004
contenttype	Fulltext

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