Dilemma between Physics and ISO Elastic Indentation Modulus

Kaupp, Gerd

doi:10.4172/2169-0022.1000402

Cited by 7 publications

(7 citation statements)

References 11 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…[17] with similar H/E ratios containing log/log plots. Unfortunately, E r numbers are not well defined and depend strongly on the details of their detection, as outlined in [9], so that one has to choose from sometimes extremely different values for E r when comparing different methods.…”

Section: The Physical Errors Of the H/e Ratio Claims With Their Usesmentioning

confidence: 99%

“…It is empirically known since 2004 [4] and 2013 with extensive table for all types of materials [5] and undoubtedly physically deduced one year before 2016 [3] and also in 2020 [6] that pyramidal and conical indentations follow the exponent 3/2 on the depth h (but not 2) in the force (F N ) vs depth curves, the slope of which is the penetration resistance, that is the physical hardness when calibrated with the indenter cone or effective cone. It was deduced in 2013 [7] and in 2017 [8] that the Oliver-Pharr iterations that are still ISO 14577 standard violate the energy law for hardness H [7] and in 2017 [8] also for E r since 2017 [9] (ISO denotes International Standardization Organization). Furthermore, elastic moduli from indentations are not "Young's moduli", as used in [1] and [2].…”

Section: Introductionmentioning

confidence: 99%

See 1 more Smart Citation

Undue Hardness/Modulus Ratio Claims instead of Physical Penetration Resistance and Applications with Mollusk Shells

Kaupp¹

2021

AMPC

Self Cite

View full text Add to dashboard Cite

The Nanoindentation is a precise technique for the elucidation of mechanical properties. But such elucidation requires physically based interpretation of the loading curves that is widely still not practiced. The use of indentation hardness H and indentation modulus E r is unphysical and cannot detect the most important phase-transitions under load that very often occur. The claim that H versus E plots relate linearly for all different materials is neither empirically found nor correctly deduced. It is most dangerous by producing incorrect materials properties and misleading. The use of H/E (that is also called "elasticity index") in complicated formulas for brittle parameter, yield strength, toughness, and so-called "true hardness" is also in error. The use of H/E cannot reveal the true qualities of materials without considering phase-transitions under load that require the correct exponent 3/2 on h for the loading curves (instead of disproved 2). This is exemplified with the physical data of different mollusk shells that experience phase-transitions, a new bionics model, and different contributions for their strengthening. The data are compared to the ones of aragonite and calcite and vaterite.

show abstract

Section: The Physical Errors Of the H/e Ratio Claims With Their Usesmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Undue Hardness/Modulus Ratio Claims instead of Physical Penetration Resistance and Applications with Mollusk Shells

Kaupp¹

2021

AMPC

Self Cite

View full text Add to dashboard Cite

show abstract

“…The first goals of indentations are hardness and elastic modulus and when these are unphysical, their errors are perpetuated in the there from defined further characterizations of the materials. For example 12 different applications of the indentation modulus from viscoelasticity to fracture toughness are listed in [18].…”

Section: The Presumed "Spherical" Nickel-superalloy Indentationmentioning

confidence: 99%

The Loading Curve of Spherical Indentions Is Not a Parabola and Flat Punch Is Linear

Kaupp¹

2019

AMPC

Self Cite

View full text Add to dashboard Cite

The purpose of this paper is the physical deduction of the loading curves for spherical and flat punch indentations, in particular as the parabola assumption for not self-similar spherical impressions appears impossible. These deductions avoid the still common first energy law violations of ISO 14577 by consideration of the work done by elastic and plastic pressure work. The hitherto generally accepted "parabolas" exponents on the depth h ("2 for cone, Advances in Materials Physics and Chemistry, 9, 141-157. Spherical indentations reveal that linear data regression is suspicious and worthless if it does not correspond with physical reality. This stresses the necessity of the straightforward deductions of the correct relations on the basis of iteration-less and fitting-less undeniable calculation rules on an undeniable basic physical understanding. The straightforward physical deduction of the flat punch indentation is therefore also presented, together with formulas for the physical indentation hardness, indentation work, and applied work for these geometrically self-similar indentations. It is exemplified with a macroindentation.

show abstract

“…The second obvious error is claiming "Young's modulus" that is a unidirectional property, totally different from an indentation modulus. A very complex "equation for fitting" of the depth values is published as equation (9) in (6) [6] is penetration depth; P is "load" (force). The "fit parameters" are a 0 and P adh .…”

Section: Introductionmentioning

confidence: 99%

“…The therefrom determined "Young's moduli" are dangerously misleading. The enormous trouble when Young's moduli are equalized with indentation moduli has been amply exemplified in [9]. The publication of moduli from "fitted" data [6] They shall help to repeat the mechanical characterization with true experimental data, when these are unavailable from the recent authors for genuine publications.…”

Section: Introductionmentioning

confidence: 99%

Real and Fitted Spherical Indentations

Kaupp¹

2020

AMPC

Self Cite

View full text Add to dashboard Cite

Spherical indentations that rely on original date are analyzed with the physically correct mathematical formula and its integration that take into account the radius over depth changes upon penetration. Linear plots, phase-transition onsets, energies, and pressures are algebraically obtained for germanium, zinc-oxide and gallium-nitride. There are low pressure phase-transitions that correspond to, or are not resolved by hydrostatic anvil onset pressures. This enables the attribution of polymorph structures, by comparing with known structures from pulsed laser deposition or molecular beam epitaxy and twinning. The spherical indentation is the easiest way for the synthesis and further characterization of polymorphs, now available in pure form under diamond calotte and in contact with their corresponding less dense polymorph. The unprecedented results and new possibilities require loading curves from experimental data. These are now easily distinguished from data that are "fitted" to make them concur with widely used unphysical Johnson's formula for spheres (" () 3 2 1 2 4 3 P h R E * = ") not taking care of the R/h variation. Its challenge is indispensable, because its use involves "fitting equations" for making the data concur. These faked reports (no "experimental" data) provide dangerous false moduli and theories. The fitted spherical indentation reports with radii ranging from 4 to 250 µm are identified for PDMS, GaAs, Al, Si, SiC, MgO, and Steel. The detailed analysis reveals characteristic features.

show abstract

Dilemma between Physics and ISO Elastic Indentation Modulus

Cited by 7 publications

References 11 publications

Undue Hardness/Modulus Ratio Claims instead of Physical Penetration Resistance and Applications with Mollusk Shells

Undue Hardness/Modulus Ratio Claims instead of Physical Penetration Resistance and Applications with Mollusk Shells

The Loading Curve of Spherical Indentions Is Not a Parabola and Flat Punch Is Linear

Real and Fitted Spherical Indentations

Contact Info

Product

Resources

About