Modified flat-punch model for hyperelastic polymeric and biological materials in nanoindentation. (March 2018)
- Record Type:
- Journal Article
- Title:
- Modified flat-punch model for hyperelastic polymeric and biological materials in nanoindentation. (March 2018)
- Main Title:
- Modified flat-punch model for hyperelastic polymeric and biological materials in nanoindentation
- Authors:
- Chang, Alice Chinghsuan
Liu, Bernard Haochih - Abstract:
- Highlights: Similar mechanical behaviors of the microbial cells and the hyperelastic material were observed by nanoindentation, where the conventional contact-mechanism models failed to correctly describe the deformational procedure and resulted in the high error in modulus evaluation. The power-law of applied force and sample deformation was adapted and the parameters were adjusted by connecting the measurements by compression tests and nanoindentation. The proposed equation effectively eliminated the influence of sample deformation on computed modulus and enabled researchers to obtain a reliable and precise mechanical property of the material. The Gram-positive microbes were typified with higher elastic modulus than the Gram-negative one, which was consistent with the differences in the bacterial membrane/wall – the thicker and more stable structures for the Gram-positive microbes. Abstract: Nanoindentation can characterize in-situ elastic modulus E of an object by pressing an indenter into the sample surface and fitting the detected data to a contact equation. In this work, we found the conventional contact-mechanism theory resulted in a high uncertainty of E for the hyperelastic materials, including some polymers and biological cells. The evaluated E displayed an exponential decrease with increasing indent distance when fitting to Hertz model and caused high E variance as a function of indent depth. To obtain a reliable E of those specimens, a new equation for EHighlights: Similar mechanical behaviors of the microbial cells and the hyperelastic material were observed by nanoindentation, where the conventional contact-mechanism models failed to correctly describe the deformational procedure and resulted in the high error in modulus evaluation. The power-law of applied force and sample deformation was adapted and the parameters were adjusted by connecting the measurements by compression tests and nanoindentation. The proposed equation effectively eliminated the influence of sample deformation on computed modulus and enabled researchers to obtain a reliable and precise mechanical property of the material. The Gram-positive microbes were typified with higher elastic modulus than the Gram-negative one, which was consistent with the differences in the bacterial membrane/wall – the thicker and more stable structures for the Gram-positive microbes. Abstract: Nanoindentation can characterize in-situ elastic modulus E of an object by pressing an indenter into the sample surface and fitting the detected data to a contact equation. In this work, we found the conventional contact-mechanism theory resulted in a high uncertainty of E for the hyperelastic materials, including some polymers and biological cells. The evaluated E displayed an exponential decrease with increasing indent distance when fitting to Hertz model and caused high E variance as a function of indent depth. To obtain a reliable E of those specimens, a new equation for E computation directly adopting the mechanical behavior of the sample was proposed. Indenting on hyperelastic polydimethylsiloxane (PDMS), we observed linear force-displacement curves and used its power-law for the selection of the correct equation. The flat-punch model was thus chosen and showed constant E independent of the indent size, which meant the indent depth in this paper. After eliminating the depth effect on E, we referred the nanoindentation results to the bulk E of PDMS for the revision of the flat-punch model. A new equation was generated and displayed the improvement on not only the precision (remove depth effect) but also the accuracy (compare to compression test) of E for PDMS. The suitability of the modified flat-punch model for hyperelastic material implied the practical deformational mechanism different from the general idea. Applied on microbial samples, our new equation characterized two bacteria and showed consistent results with their membrane structures. In conclusion, we suggest the modified flat-punch model improves the description of mechanical behaviors and derived the correct E for hyperelastic materials. Graphical abstract: Image, graphical abstract Figure G. The illustration of the deformational mechanism of the elastic matters corresponding to the detected force curve, which consisted of three parts, (A) the contribution of sample deformation and surface tension, (B) the break of the sample surface and the formation of crack, and (C) the propagation of crack thorough the specimen. … (more)
- Is Part Of:
- Mechanics of materials. Volume 118(2018:Mar.)
- Journal:
- Mechanics of materials
- Issue:
- Volume 118(2018:Mar.)
- Issue Display:
- Volume 118 (2018)
- Year:
- 2018
- Volume:
- 118
- Issue Sort Value:
- 2018-0118-0000-0000
- Page Start:
- 17
- Page End:
- 21
- Publication Date:
- 2018-03
- Subjects:
- Nanoindentation -- Hyperelastic materials -- Deformation mechanism -- Flat-punch model
Strength of materials -- Periodicals
Mechanics, Applied -- Periodicals
Résistance des matériaux -- Périodiques
Mécanique appliquée -- Périodiques
Mechanics, Applied
Strength of materials
Periodicals
Electronic journals
620.11 - Journal URLs:
- http://www.sciencedirect.com/science/journal/01676636 ↗
http://books.google.com/books?id=hWtTAAAAMAAJ ↗
http://www.elsevier.com/journals ↗
http://www.elsevier.com/homepage/elecserv.htt ↗ - DOI:
- 10.1016/j.mechmat.2017.12.010 ↗
- Languages:
- English
- ISSNs:
- 0167-6636
- Deposit Type:
- Legaldeposit
- View Content:
- Available online (eLD content is only available in our Reading Rooms) ↗
- Physical Locations:
- British Library DSC - 5424.105000
British Library DSC - BLDSS-3PM
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